JP2008061620A - Combine harvester - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve a problem that, because of the presence of a ridge-matching switch at a position enabling making a control without letting the operator's hand off the steering wheel, a manually inputting mechanism may be contacted by accident in making a turning operation of the steering wheel during traveling on the road, resulting in the traveling machine body's turning in an unexpected direction, in a combine harvester where the wheel part of a steering wheel is furnished with a steering switch for making a fine control of the advancing direction of the traveling machine body. <P>SOLUTION: When a reaping part is at a non-reaping height level H1 and all of three grain culm passage sensors 54 are detecting the absence of grain culms, a transverse operation of the steering switch 100 is restricted (is not made to function) and the traveling machine body's ridge-matching operation is not performed. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a self-propelled, self-removing combiner in which a harvesting part for continuously harvesting planted cereal straw in a field is attached to the front part of the traveling machine body. More specifically, the steering operation is performed on the traveling machine body. It is related with the structure for.

  Conventionally, a combine is configured to transmit the power of an engine mounted on a traveling machine body to left and right traveling crawlers via a straight driving means and a turning driving means.

  An example of a combine having such a configuration is disclosed in Patent Document 1. In the combine of Patent Document 1, the drive output amount of the straight drive means, that is, the straight traveling speed of the traveling machine body is adjusted according to the operation amount of the main transmission lever provided in the control unit of the traveling machine body. If the main shift lever is in the neutral position, the traveling aircraft does not go straight.

  On the other hand, the drive output amount of the turning drive means, that is, the traveling (turning) direction and turning speed of the traveling vehicle body is determined by the turning direction and rotation of the round steering handle erected in front of the control seat in the control unit. It is adjusted according to the amount of dynamic operation.

The steering wheel portion of the steering handle is provided with an alignment switch as manual input means. The alignment switch is for finely adjusting (finely correcting) the traveling direction of the traveling machine body to the left and right, and is configured to be tiltable to the left and right with the root portion as a rotation fulcrum. When the alignment switch is tilted to the left or right, the traveling machine body makes a slight turn to the left and right, and the alignment is performed so that the weeding body of the cutting unit is aligned with the planted grain rows in the field.
Japanese Patent Laid-Open No. 9-248039

  By the way, according to the description of Patent Document 1, the alignment switch is provided on the right hand side grip portion of the handle wheel portion, and the operator tilts the alignment switch to the left and right even while holding the handle wheel portion. it can.

  However, in the configuration of Patent Document 1, since the alignment switch is present at a position where it can be operated without removing the hand from the steering handle, for example, when the traveling machine body normally turns during traveling on the road, the alignment switch is erroneously set. There is a risk of contact.

  If the steering handle is touched while the steering handle is being rotated while traveling on the road, the traveling aircraft will turn in unexpected directions (for example, meander). Therefore, there was a problem of lack of safety when driving on the road.

  Therefore, the present invention has as a technical problem to eliminate a problem caused by the steering handle and the manual input means coexisting.

  In order to solve this technical problem, the invention of claim 1 transmits power from an engine mounted on a traveling machine body to a cutting part and a traveling part, which are mounted on the front part of the traveling machine body so as to be adjustable up and down. A steering wheel handle for changing the traveling direction of the traveling machine body, and a steering wheel portion of the steering handle includes a traveling direction of the traveling machine body. And a manual input means for finely adjusting the chopping portion, wherein the reaping part is provided with a culm detection means for detecting the presence or absence of the culm in the reaping part. In a state where the portion is at a non-cutting height position higher than a preset cutting height position set in advance and the culm detection means detects no culm, the operation of the manual input means is regulated. Is composed of .

  While the invention of claim 2 is configured to transmit the power from the engine mounted on the traveling machine body to the cutting part and the traveling part that are mounted on the front part of the traveling machine body so as to be adjustable in elevation, A rotating steering handle for changing the traveling direction of the traveling aircraft body is provided, and a manual input for finely adjusting the traveling direction of the traveling aircraft body is provided on a handle wheel portion of the steering handle. A combine having a means, wherein the reaping part is provided with a culm detection means for detecting the presence or absence of the culm in the reaping part, wherein the reaping part is lower than the non-cutting height position. It is configured to allow the operation of the manual input means when it is in a position or in a state in which the wrinkle detection means detects the presence of a wrinkle.

  By the way, the operator raises the cutting unit to a non-cutting height position higher than a preset set cutting height position when it is in a non-farm working state such as traveling on a road or over a ridge, that is, when no cutting work is performed. . In this case, if there is no grain culm in the reaper, it is clear that the reaping operation is not performed.

  On the other hand, according to the invention of claim 1, the reaping part is in the non-cutting height position, and the cereal detection means for detecting the presence or absence of the culm in the reaping part detects the absence of the culm. In this state, the operation of the manual input means for finely adjusting the traveling direction of the traveling machine body is restricted (not functioned). In this state, the manual input means may be accidentally touched. Even so, the turning motion (alignment operation) of the traveling machine body by the manual input means is not executed. For this reason, at the time of non-farm work such as traveling on the road, it is possible to reduce the risk that the traveling machine body will turn in an unexpected direction (meandering or turning left and right more than expected) against the intention of the operator. There is an effect that the driving safety of the vehicle is improved.

  According to the invention of claim 2, in a state where the cutting part is at a position lower than the non-cutting height position or the culm detection means detects the presence of the culm, the operation of the manual input means is allowed. Because it is configured, for example, even if it does not have a dedicated switching operation means (switch, lever, etc.) for selectively switching between a state where the manual input means can function and a state where it does not function, harvesting and threshing work with a combine In the course of a series of operations when performing the above, the manual input means can be automatically switched to a state where it can function. Therefore, although it is a manual input means in consideration of erroneous operation and malfunction prevention, there is an effect that its operability is remarkably improved.

  DESCRIPTION OF EMBODIMENTS Embodiments embodying the present invention will be described below with reference to the drawings (FIGS. 1 to 15). 1 is a side view of the combine, FIG. 2 is a plan view of the combine, FIG. 3 is a schematic front view showing the arrangement relationship of each device in the cutting part, FIG. 4 is a schematic plan view of the front part in the cutting part, and FIG. FIG. 6 is a skeleton diagram of a power transmission system in a combine, FIG. 7 is a skeleton diagram showing a power transmission system in a transmission case, FIG. 8 is a hydraulic circuit diagram of the combine, and FIG. 9 is a main shift lever. FIG. 10 is a plan view of the steering unit, FIG. 11 is an enlarged plan view of the steering handle, and FIG. 12 is a functional block diagram of the controller. FIG. 13 is a flowchart for explaining the first embodiment of the steering switch operation control, FIG. 14 is a flowchart for explaining the second embodiment of the steering switch operation control, and FIG. 15 is the steering hand. It is an enlarged plan view showing another example of.

(1). First, the schematic structure of the combine will be described with reference to FIGS. 1 and 2.

  The self-propelled self-removing combine for cutting six strips in the embodiment includes a traveling machine body 1 supported by a pair of left and right traveling crawlers 2 as traveling portions. At the front part of the traveling machine body 1, a harvesting part 3 that is taken in while harvesting a planted grain culm C (uncut grain culm, see FIG. 4) in the field is mounted by a single-acting hydraulic cylinder 4 so as to be adjustable up and down. Yes.

  A threshing unit 6 with a feed chain 7 and a grain tank 8 for storing grain after threshing are mounted on the traveling machine body 1 side by side. In the embodiment, the threshing unit 6 is disposed on the left side in the traveling direction of the traveling machine body 1, and the grain tank 8 is disposed on the right side in the traveling direction of the traveling machine body 1.

  A control unit 9 is provided between the harvesting unit 3 and the grain tank 8. A round steering handle 10 for changing the traveling (turning) direction and turning speed of the traveling machine body 1, a control seat 11 on which an operator is seated, and the like are disposed in the control unit 9. An engine 12 as a power source is disposed below the control unit 9. A mission case 13 is disposed in front of the engine 12 for appropriately shifting the power from the engine 12 and transmitting it to the left and right traveling crawlers 2.

  The mowing unit 3 includes a clipper-type cutting blade device 14, a culm pulling device 15 for six strips, a culm transporting device 16, and a weeding body 17 (seven in the embodiment). The cutting blade device 14 is disposed below the cutting frame 5 constituting the framework of the cutting unit 3. The grain raising device 15 is disposed above the cutting frame 5. The corn straw transporting device 16 is disposed between the corn straw pulling device 15 and the front end of the feed chain 7. The weeding body 17 protrudes in front of the lower part of the grain raising device 15. The harvested cereal grains harvested by the harvesting unit 3 are transferred to the feed chain 7 and threshed by the threshing unit 6.

  In the handling room of the threshing unit 6, a handling cylinder 18 for threshing the harvested cereal meal is built. Below the handling cylinder 18, a sorting device 20 is arranged for performing rocking sorting using a handling net, chaff sheave, or the like and wind sorting using the wind of a Kara fan. After the sorting by the sorting device 20, the first thing such as fine grains collected in the first receiving bowl (not shown) at the bottom of the traveling machine body 1 is the first conveyor and the cereal conveyor (both not shown). ) To the grain tank 8.

  The second item such as the grain with branch stems is sent to the processing drum 19 through the second receiving rod and the reduction conveyor (both not shown) behind the first receiving rod, and is again recycled by the processing drum 19. Threshed. The second item after the threshing is returned to the sorting device 20 and re-sorted.

  The sawdust is sucked into a suction fan (not shown) disposed at the rear part of the threshing unit 6 and then discharged to the outside of the traveling machine body 1 through a discharge port formed at the rear part of the traveling machine body 1. The grain in the grain tank 8 is carried out of the traveling machine body 1 through the discharge auger 21.

  The waste handed over from the rear end of the feed chain 7 to the waste chain 22 (see FIG. 2) is discharged to the rear of the traveling machine body 1 in a long state or is sent to a waste cutter (not shown). After being cut to a short length as appropriate, it is discharged to the rear of the traveling machine body 1.

(2). Next, the structure of the cutting unit will be described with reference mainly to FIGS. 3 and 4.

  As described above, the cutting unit 3 includes the hair clipper-type cutting blade device 14, the culm pulling device 15 for six strips, the culm conveying device 16, and the weed body 17.

  The grain raising device 15 includes a raising case 30 for six strips having a raising tine 31 for raising a planted grain cake C (uncut grain rice cake) taken through the weed body 17 and the rear of each of the raising cases 30. It is constituted by a star wheel 32 and a scraping belt 33 arranged in the lower part. The star wheel 32 and the scraping belt 33 are used to scrape the root part of the uncut grain caused by the pulling tine 31 corresponding to these sets backward. The root portion of the planted cereal cake C that has been scraped by the star wheel 32 and the scraping belt 33 is cut by the clipper type cutting blade device 14.

  The grain transporter 16 includes a lower right transport chain 34 and an upper right transport tine 35, a central lower transport chain 36 and a central upper transport tine 37, a lower left transport chain 38 and a left upper transport tine 39, and a vertical transport chain 40. And a vertical conveying tine 41, a first auxiliary conveying chain 42 and a second auxiliary conveying chain 43.

  The lower right transport chain 34 and the upper right transport tine 35 are for transporting the right two chopped grains into the left diagonally rearward direction. The center lower transport chain 36 and the center upper transport tine 37 are for transporting the middle two reaped cereal grains in the rear to join the vicinity of the feeding intermediate portion of the lower right transport chain 34 and the upper right transport tine 35. is there. The lower left transport chain 38 and the upper left transport tine 39 are used to transport the left two chopped grains into the right diagonally rearward direction and join the vicinity of the feed end portions of the lower right transport chain 34 and the upper right transport tine 35. Is.

  The vertical conveying chain 40 is used for inheriting and conveying to the feed chain 7 the root portions of the six reaped cereal mashes (hereinafter referred to as the merging cereal cocoons) joined at the feed end portion of the lower right conveying chain 34. . The vertical transport tine 41 is for transporting the head portion of the combined cereal mash that has joined at the feed end portion of the upper right transport tine 35 to the threshing unit 6. The 1st auxiliary conveyance chain 42 and the 2nd auxiliary conveyance chain 43 are for relaying conveyance of the middle part near the root of the merging cereal between the vertical conveyance chain 40 and the feed chain 7.

  The root portion of the combined cereal mash that has been sent in a lying position by the vertical conveying chain 40 is inherited by the starting end of the feed chain 7 via the first and second auxiliary conveying chains 42 and 43. Then, the tip portion of the combined cereal mash is threshed by the handling cylinder 18 in the handling chamber of the threshing unit 6.

  As shown in FIG. 4, the bottom surface of the second weed body 17 of the seven weed bodies 17 counting from the right end protrudes leftward and can be rotated counterclockwise in a plan view of FIG. A left steering sensor 50 with an antenna lever 52 and a right steering sensor 51 with an antenna lever 53 that protrudes to the right and can be rotated clockwise in a plan view of FIG. 4 are arranged.

  The left and right steering sensors 50 and 51 detect whether or not the antennal levers 52 and 53 are in contact with the planted grain culm C (uncut grain culm) in the field, whereby the traveling machine body 1 is in a predetermined direction. It is of a contact type (limit switch type) that detects whether or not the vehicle is traveling along (for example, a strip direction described later).

  The distance between the tips of both antennal levers 52 and 53 is set to be shorter than the stock interval L in the row direction in the field (planting direction at the time of rice planting, see X direction in FIG. 4). For this reason, the left and right steering sensors 50 and 51 do not sense the planted culm C at the same time when the traveling machine body 1 is cut in the row direction (X direction in FIG. 4). In general, the stock interval L in the strip direction is about 30 cm.

  As shown in FIG. 4, the culm passing sensor 54 (in the embodiment, for detecting whether or not the chopped culm taken into the reaping part 3 has passed through the lower front end side of the culm pulling device 15. 3) is arranged for each cereal passage portion for two strips. The grain pass sensor 54 is also of a contact type (limit switch type) similar to the left and right steering sensors 50 and 51 described above. That is, by detecting whether or not the sensing body 55 protruding from each culm passage sensor 54 toward the culm passage location is in contact with the chopped culm, the harvested culm in the middle of the chopping unit 3 is conveyed. It is to detect whether or not there is.

  As shown in FIGS. 2 and 4, the height of the cutting unit 3 to the ground (relative to the field scene) An ultrasonic sensor 56 for detecting the height of the cutting unit 3 is attached with the transmitter (horn unit) of the transmitter and the receiver of the receiver facing the farm scene. The ground height of the cutting unit 3 is obtained from the detection value of the ultrasonic sensor 56. When the installation height of the ultrasonic sensor 56 and the installation height of the cutting blade device 14 are different, the ground height of the cutting unit 3 is obtained by a predetermined conversion based on the detection value of the ultrasonic sensor 56.

  Although not shown in detail, the height of the cutting unit 3 relative to the machine body (relative height of the cutting unit 3 with respect to the traveling machine body 1) is detected at the proximal end portion of the cutting frame 5 near the rotation center. A lift position sensor 57 (see FIG. 12) is attached. The height of the cutting unit 3 with respect to the machine body is obtained from the up and down rotation angle of the cutting frame 5 detected by the up / down position sensor 57.

(3). Next, the power transmission system of the combine will be described with reference to FIGS.

  In the self-propelled self-removing combine according to the embodiment, the power from the engine 12 is appropriately changed by the hydraulic drive device 62 or the like in the mission case 13, and the drive output shaft 24 protrudes outward from the mission case 13 left and right. And output to the left and right drive wheels 25.

  The engine 12 includes an output shaft 60 that protrudes forward and backward. One of the power from the engine 12 is transmitted from the front end of the output shaft 60 to the hydraulic drive device 62 in the mission case 13 through the universal joint shaft 61 and the input shaft 59 of the mission case 13.

  In the transmission case 13, a differential gear mechanism having a hydraulic drive device 62 for shifting the power from the engine 12, a sub-transmission mechanism 85 having a plurality of shift stages, a pair of left and right planetary gear mechanisms 157, and the like. 86 is installed (see FIG. 7).

  The hydraulic drive device 62 includes a straight traveling HST transmission mechanism 63 including a first hydraulic pump 150 and a first hydraulic motor 151, and a turning HST transmission mechanism 64 including a second hydraulic pump 152 and a second hydraulic motor 153. It has.

  The power from the output shaft 60 toward the hydraulic drive device 62 is transmitted to the linear pump shaft 65 of the first hydraulic pump 150 and the turning pump shaft 66 of the second hydraulic pump 152, respectively. In the straight traveling HST transmission mechanism 63, hydraulic oil is appropriately fed from the first hydraulic pump 150 toward the first hydraulic motor 151 by the power transmitted to the straight traveling pump shaft 65. Similarly, in the turning HST transmission mechanism 64, hydraulic oil is appropriately sent from the second hydraulic pump 152 toward the second hydraulic motor 153 with the power transmitted to the turning pump shaft 66.

  A charge pump 179 for supplying hydraulic oil to the hydraulic pumps 65 and 66 and the hydraulic motors 67 and 68 is mounted on the turning pump shaft 66. The charge pump 179 can be interlocked with the turning pump shaft 66 and is driven by the rotational power of the engine 12.

  In the straight traveling HST transmission mechanism 63, the first hydraulic pump 150 has a function corresponding to the shift position of a main transmission lever 131 (details will be described later) arranged in the control unit 9 and the amount of rotation of the steering handle 10. By changing and adjusting the inclination angle of the rotary swash plate 180 (see FIG. 8) and changing the discharge direction and discharge amount of the hydraulic oil to the first hydraulic motor 151, the straight travel protruding left and right from the first hydraulic motor 151 It is comprised so that the rotation direction and rotation speed of the motor shaft 67 may be adjusted arbitrarily.

  The rotational power of the linear motor shaft 67 in the first hydraulic motor 151 is transmitted to a sub-transmission mechanism 85, which is a conventionally known gear mechanism, and a counter, which will be described later, via a pulley / belt transmission system and a cutting clutch 82. The signal is also branched and transmitted from the case 72 to the tuning input shaft 75 (see FIG. 6) that protrudes toward the center of the traveling machine body 1.

  The sub-transmission mechanism 85 operates the sub-transmission lever 132 (details will be described later) disposed in the control unit 9 to reduce the adjustment range of the rotational power (rotation direction and number of rotations) from the linear motor shaft 67 at a low speed. It is configured to be switchable to three speed stages, high speed and neutral. The brake shaft 154, which is a component of the auxiliary transmission mechanism 85, is provided with a parking brake means 155 such as a wet multi-plate disk.

  The rotational power from the auxiliary transmission mechanism 85 is transmitted to the differential gear mechanism 86 from the auxiliary transmission output gear 156 fixed to the brake shaft 154. The differential gear mechanism 86 includes a pair of left and right planetary gear mechanisms 157 and a relay shaft 158 positioned between the planetary gear mechanism 157 and the brake shaft 154. A center gear 159 fixed to the center portion of the relay shaft 158 meshes with the auxiliary transmission output gear 156 of the brake shaft 154. The side gears 160 fixed to the left and right sides of the relay shaft 158 with the center gear 159 interposed therebetween mesh with the outer peripheral surfaces of the corresponding ring gears 165 (details will be described later).

  The pair of left and right planetary gear mechanisms 157 are formed symmetrically and includes a pair of left and right carriers 161 that rotatably support a plurality of planetary gears 162 on the same radius. These two carriers 161 are arranged so as to oppose each other at an appropriate interval on the same axis.

  Sun gear members 164 are pivotally supported on the left and right sides of the sun shaft 163 located between the left and right carriers 161. Each sun gear member 164 meshes with each planetary gear 162 of the carrier 161 corresponding thereto. The left and right ends of the sun shaft 163 are rotatably supported by bearings positioned at the rotation center of each carrier 161.

  A pair of left and right ring gears 165 having inner teeth on the inner peripheral surface and outer teeth on the outer peripheral surface are arranged concentrically with the sun shaft 163 so that the inner teeth mesh with the plurality of planetary gears 162. . Each ring gear 165 is rotatably supported via a bearing on a drive output shaft 24 that protrudes left and right outward from the outer surface of the carrier 161.

  The rotational power from the subtransmission mechanism 85 is transmitted to the left and right planetary gear mechanisms 157 via the left and right side gears 160 in the relay shaft 158. The rotational power transmitted to the left and right planetary gear mechanisms 157 is transmitted to the drive output shaft 24 of each carrier 161 at the same rotational speed in the same direction.

  On the other hand, in the turning HST type transmission mechanism 64, the inclination angle of the rotary swash plate 182 (see FIG. 8) in the second hydraulic pump 152 in accordance with the amount of turning operation of the steering handle 10 disposed in the control unit 9. And adjusting the rotation direction and the number of rotations of the turning motor shaft 68 protruding from the second hydraulic motor 153 by changing the discharge direction and discharge amount of the hydraulic oil to the second hydraulic motor 153. Is configured to do.

  A turning output gear 166 is rotatably supported on the turning motor shaft 68. Further, a steering brake means 167 for braking this and the turning output gear 166 is provided at the tip of the turning motor shaft 68.

  The rotational power of the turning motor shaft 68 in the second hydraulic motor 153 is transferred from the turning output gear 166 of the turning motor shaft 68 through the transmission gear 170 of the clutch shaft 168 having the steering clutch means 169. 171 and the reverse gear 172. The forward rotation gear 171 meshes with one (right in the embodiment) of a pair of left and right input gears 173 that are rotatably supported around the sun shaft 163. The reverse gear 172 meshes with the other input gear 173 (left in the embodiment). The left and right input gears 173 are configured to rotate integrally with the corresponding sun gear members 164.

  When the right sun gear member 164 is normally rotated (reversely rotated) at a predetermined rotational speed via the normal rotation gear 171 and the right input gear 173 by the normal rotation (reverse rotation) of the second hydraulic motor 153, the left sun gear The member 164 reversely rotates (forward rotation) at the same rotational speed as the right sun gear member through the reverse rotation gear and the left input gear. The rotational power transmitted to the left and right planetary gear mechanisms 157 via the left and right sun gear members 164 is transmitted to the drive output shafts 24 of the left and right carriers 161 at the same rotational speeds in opposite directions.

  As can be seen from the above, the shift output from the straight motor shaft 67 and the turning motor shaft 68 is transmitted to the drive wheels 25 of the left and right traveling crawlers 2 via the auxiliary transmission mechanism 85 and the differential gear mechanism 86. As a result, the vehicle speed (traveling speed) and the traveling direction of the left and right traveling crawlers 2 and thus the traveling machine body 1 are determined.

  That is, when the straight motor shaft 67 is driven in the forward or reverse rotation direction with the drive of the turning motor shaft 68 stopped, the rotational power from the straight motor shaft 67 is transmitted to the sub-transmission mechanism 85 and the differential gear. Via the mechanism 86, it is transmitted to the drive wheels 25 of the left and right traveling crawlers 2 at the same rotational speed in the same direction, and the traveling machine body 1 travels straight. In this case, the traveling machine body 1 moves forward when the straight-travel motor shaft 67 (straight-travel HST transmission mechanism 63) is driven in the forward rotation direction, and the traveling machine body 1 moves backward when driven in the reverse rotation direction.

  On the other hand, when the turning motor shaft 68 is driven in the normal or reverse rotation direction with the driving of the linear motor shaft 67 stopped, the turning power from the turning motor shaft 68 via the differential gear mechanism 86 is used. One of the drive wheels 25 of the left and right traveling crawlers 2 rotates forward and the other rotates backward, and the traveling machine body 1 spin-turns on the spot.

  Further, when the turning motor shaft 68 is driven while the linear motor shaft 67 is driven, a difference occurs in the driving speed of the left and right traveling crawlers 2, and the traveling machine body 1 turns larger than the spin turn turning radius while moving forward or backward. Turn left or right at the radius. The turning radius at this time is determined according to the difference in driving speed between the left and right traveling crawlers 2.

  A cooling fan 175 for a radiator is attached to the fan shaft 174 that relays power between the linear pump shaft 65 and the turning pump shaft 66 and the input shaft 59 of the transmission case 13. In the embodiment, the power is transmitted from the fan shaft 174 to both the straight traveling pump shaft 65 and the turning pump shaft 66 via the transmission gear mechanism 176.

  In the embodiment, the power transmitted from the fan shaft 174 to the linear pump shaft 65 via the transmission gear mechanism 176 is transmitted to the vehicle speed constant speed clutch 177, the vehicle speed constant speed mechanism, and the like. It is configured to be able to directly transmit to the subtransmission mechanism 85 via 178 and the linear motor shaft 67. For this reason, when the vehicle speed constant speed clutch 177 is in the engaged state, the power from the engine 12 is directly transmitted to the subtransmission mechanism 85 without passing through the HST transmission mechanism 63 for straight travel. The traveling machine body 1 travels at a constant vehicle speed by rotational driving.

  On the other hand, other power from the engine 12 is branched and transmitted from the rear end of the output shaft 60 in two directions: the discharge auger 21 and the counter case 72 disposed on one side of the engine 12.

  The branching power from the output shaft 60 toward the discharge auger 21 is transmitted to the bottom conveyor 70 and the vertical conveyor (not shown) in the grain tank 8 via the discharge clutch 69, and then the discharge conveyor ( (Not shown).

  The branching power from the output shaft 60 toward the counter case 72 is transmitted to the threshing input shaft 73 of the counter case 72 via the threshing clutch 71, and further branched and transmitted from the threshing input shaft 73 in two directions.

  A part of the power transmitted to the threshing input shaft 73 is transmitted to the rotating shaft of the handling cylinder 6 and the processing cylinder 19 (not shown in FIG. 6) via the pulley / belt transmission system, and the handling cylinder 6 and the processing. The body 19 is driven to rotate. Other power from the threshing input shaft 73 is transmitted to the constant speed rotating shaft 74 of the counter case 72 via a bevel gear mechanism provided in the middle thereof.

  Here, the counter case 72 includes the threshing input shaft 73 and the constant speed rotation shaft 74 described above, the tuning input shaft 75, the vehicle speed tuning shaft 76, the cutting transmission shaft 77, and the FC input extending in parallel with the constant speed rotation shaft 74. A cutting speed change mechanism 79 associated with the shaft 78, the tuning input shaft 75 and the vehicle speed tuning shaft 76, a cutting constant speed mechanism 80 associated with the constant speed rotating shaft 74 and the vehicle speed tuning shaft 76, and the vehicle speed tuning shaft 76. And an FC transmission mechanism 81 associated with the FC input shaft 78.

  Part of the power transmitted to the constant speed rotating shaft 74 is transmitted to a sorting device (not shown), the waste chain 22 (not shown in FIG. 6), etc. via a pulley / belt transmission system. The other power from the constant speed rotating shaft 74 is transmitted to the vehicle speed tuning shaft 76 via the cutting constant speed mechanism 80 when the cutting unit 3 is not driven in synchronization with the vehicle speed (traveling speed). Power is transmitted from 76 to the devices 14 to 16 of the cutting unit 3 through the cutting transmission shaft 77.

  On the other hand, a part of the rotational power of the linear motor shaft 67 is transmitted to the tuning input shaft 75 via a reaping clutch 82 as a working clutch. The rotational power transmitted to the tuning input shaft 75 is transmitted to the vehicle speed tuning shaft 76 via the one-way clutch 83 and the cutting speed change mechanism 79 when the cutting unit 3 is driven in synchronization with the vehicle speed. Power is transmitted to the devices 14 to 16 of the cutting unit 3 through the transmission shaft 77. The one-way clutch 83 is configured to transmit power only when the linear motor shaft 67 rotates forward.

  The power transmitted to the vehicle speed tuning shaft 76 is transmitted to the FC input shaft 78 via the FC transmission mechanism 81 and the FC clutch 84, and the feed chain 7 is driven to rotate by the power transmission from the FC input shaft 78. It is configured.

(4). Combined Hydraulic Circuit Structure Next, the combined hydraulic circuit structure will be described with reference to FIG.

  The combine hydraulic circuit 190 shown in FIG. 8 includes the above-described charge pump 179, a main transmission cylinder 191 for changing and adjusting the inclination angle of the rotary swash plate 180 in the first hydraulic pump 150, and an operation to the main transmission cylinder 191. A manual transmission valve 192 for adjusting the supply of oil and an electromagnetic neutral valve 193 for reducing the output of the first hydraulic pump 150 by a predetermined amount are provided.

  The main transmission cylinder 191 is connected to the charge pump 179 via a manual transmission valve 192 and an electromagnetic neutral valve 193. The manual transmission valve 192 is mainly configured to be switched by the main transmission lever 131. The electromagnetic neutral valve 193 is configured to automatically perform switching operation by driving an electromagnetic solenoid 194 corresponding to the neutral operation of the main transmission lever 131.

  When the manual transmission valve 192 is switched by operating the main transmission lever 131, the main transmission cylinder 191 expands and contracts, the inclination angle of the rotary swash plate 180 in the first hydraulic pump 150 is changed, and the first hydraulic motor 151 is operated. The direction and amount of hydraulic oil discharged to the tank changes. As a result, a linear shift operation is performed in which the rotation direction and the rotation speed of the linear motor shaft 67 in the first hydraulic motor 151 are steplessly changed or reversed.

  Further, a feedback operation in which the manual transmission valve 192 returns to neutral by the angle adjustment operation of the rotary swash plate 180 can be executed. That is, when the main transmission lever 131 is neutrally operated, the rotary swash plate 180 is returned to the neutral state in accordance with this operation, and the electromagnetic neutral valve 193 is automatically switched by the excitation of the electromagnetic solenoid 194. The output of the first hydraulic pump 150 is made substantially zero. As a result, the rotational drive of the linear motor shaft 67 in the first hydraulic motor 151 stops.

  An auxiliary transmission cylinder 196 for changing and adjusting the inclination angle of the rotary swash plate 181 in the first hydraulic motor 151 is connected to the charge pump 179 via an electromagnetic auxiliary transmission valve 195.

  In this case, the auxiliary transmission cylinder 196 expands and contracts by the automatic switching operation of the electromagnetic auxiliary transmission valve 195 in response to the operation of the auxiliary transmission switch (not shown), and the inclination angle of the rotary swash plate 181 in the first hydraulic motor 151 is increased. Is forcibly changed, and the output of the first hydraulic motor 151 is selectively switched between high speed and low speed.

  When the electromagnetic subtransmission valve 195 is in a neutral state, the subtransmission cylinder 196 communicates with the transmission case 13 which is also an oil tank, and the inclination angle of the rotary swash plate 181 in the first hydraulic motor 151 is set to the first hydraulic pump 150 and the first hydraulic pump 150. 1 is configured to be adjusted only with hydraulic oil in a closed circuit 197 connecting the hydraulic motor 151.

  In addition to the above-described configuration, the combine hydraulic circuit 190 adjusts the turning cylinder 201 for changing and adjusting the inclination angle of the rotary swash plate 182 in the second hydraulic pump 152, and the supply of hydraulic oil to the turning cylinder 201. A manual revolving valve 202 and an electromagnetic automatic steering valve 203 are provided.

  The swing cylinder 201 is connected to the charge pump 179 via a manual swing valve 202 and an electromagnetic automatic steering valve 203. The manual swing valve 202 is configured to be switchable mainly by the steering handle 10. The electromagnetic automatic steering valve 203 is configured to automatically perform switching operation by driving left and right steering solenoids 204 and 205.

  When the manual swing valve 202 is switched by rotating the steering handle 10, the swing cylinder 201 is expanded and contracted to change the tilt angle of the rotary swash plate 182 in the second hydraulic pump 152, and the second hydraulic motor. The discharge direction and discharge amount of hydraulic oil to 153 change. As a result, a left / right turning operation is performed in which the rotation direction and the number of rotations of the turning motor shaft 68 in the second hydraulic motor 153 are steplessly changed or reversed.

  Also in this case, it is possible to execute a feedback operation in which the manual swing valve 202 is neutrally returned by the angle adjustment operation of the rotary swash plate 182. That is, when the turning operation position of the steering handle 10 is in a neutral position N (see FIG. 11) described later, the rotary swash plate 182 is returned to the neutral state and the output of the second hydraulic pump 152 is made substantially zero. Thus, the rotational drive of the second hydraulic motor 153 due to the turning operation of the steering handle 10 is stopped.

  When the turning operation position of the steering handle 10 is in a neutral region NE (see FIG. 11), which will be described later, the manual turning valve 202 is almost functional due to the responsiveness to the turning operation of the steering handle 10 (for example). The traveling machine body 1 does not execute a turning operation in proportion to the amount of turning operation of the steering handle 10.

  In such a case, when the electromagnetic automatic steering valve 203 is automatically switched by the excitation of the left and right steering solenoids 204 and 205, the swing cylinder 201 expands and contracts, and the rotary swash plate 182 in the second hydraulic pump 152. Is changed, and the discharge direction and discharge amount of the hydraulic oil to the second hydraulic motor 153 are changed. As a result, a traveling direction correcting operation for changing the rotational direction and the rotational speed of the turning motor shaft 68 in the second hydraulic motor 153 is executed.

  On the other hand, in the embodiment, when the steering handle 10 is rotated to a position other than the neutral position N while the main transmission lever 131 is tilted to a position other than the neutral position, the operation direction and operation amount of the main transmission lever 131 are operated. The output of the first hydraulic pump 150 and thus the output of the first hydraulic motor 151 is increased or decreased in the forward and reverse directions, and the output of the second hydraulic pump 152 and thus the second hydraulic motor 153 is proportional to the amount of operation of the main transmission lever 131. It is also configured to change. In this case, the turning radius of the traveling machine body 1 becomes smaller as the main transmission lever 131 is operated to the higher speed side, and the traveling machine body 1 always has a size corresponding to the turning operation amount of the steering handle 10 regardless of the vehicle speed. It is set to turn left or right with a turning radius of.

  Conversely, the outputs of the hydraulic pumps 150 and 151 and the hydraulic motors 152 and 153 are changed in proportion to the amount of rotation of the steering handle 10. In this case, the traveling vehicle body 1 turns to the left or right with a small turning radius as the turning operation amount of the steering handle 10 increases, and the vehicle speed of the traveling vehicle body 1 decreases as the turning radius decreases. .

  When the main transmission lever 131 is in the neutral position, even if the steering handle 10 is rotated, the manual swing valve 202 is maintained in the neutral state and the output of the second hydraulic pump 152 is made substantially zero. Thus, the second hydraulic motor 153 is configured to be prevented from rotating.

  By the way, in addition to the above-described configuration, the combined hydraulic circuit 190 includes a cutting speed change cylinder 206 for operating a cutting speed change slider (not shown) that is a component of the cutting speed change mechanism 79, and a configuration of a constant cutting speed mechanism. A fixed cutting speed cylinder 207 for operating a switching slider (not shown) as an element, a threshing cylinder 208 for operating the threshing clutch 71, and a vehicle speed constant speed for operating the constant speed clutch 177. And a cylinder 209.

  The charge pump 179 is connected in parallel with a cutting speed change cylinder 206, a cutting constant speed cylinder 207, a threshing cylinder 208, and a vehicle speed constant speed cylinder 209 via valves 210 to 213, respectively. A cutting shift valve 210 is disposed between the charge pump 179 and the cutting shift cylinder 206, and a cutting constant speed valve 211 is disposed between the charge pump 179 and the cutting constant speed cylinder 207. A threshing valve 212 is disposed between the charge pump 179 and the threshing cylinder 208, and a vehicle speed constant speed valve 213 is disposed between the charge pump 179 and the vehicle speed constant speed cylinder 209.

(5). Next, a connection structure between the main transmission lever and the steering handle and the hydraulic drive unit will be described with reference to FIG.

  The main transmission lever 131 disposed in the control unit 9 is interlocked and connected to a mechanical switching unit 220 disposed in a steering column 90 (see FIG. 10) described later via a relay link mechanism 219. A handle shaft 92 that supports the steering handle 10 from below is also linked to the mechanical switching means 220.

The mechanical switching means 220 of the embodiment includes:
1. When the steering handle 10 is rotated to a position other than the neutral position N while the main speed change lever 131 is tilted to a position other than the neutral position, the traveling machine body 1 has a smaller turning radius as the amount of rotation operation increases. Turn left or right, and the smaller the turning radius, the slower the vehicle speed of the traveling machine body 1 (turning speed when moving forward and backward).
2. Even when the main transmission lever 131 is tilted in either the forward or backward direction, the turning operation direction of the steering handle 10 and the turning direction of the traveling machine body 1 coincide (when the steering handle 10 is turned to the right, the vehicle travels. Aircraft 1 turns right, and if steering handle 10 is turned to the left, traveling machine 1 turns left)
3. When the main transmission lever 131 is in the neutral position, it does not function even if the steering handle 10 is operated.
In order to execute various operations, the operating force from the main transmission lever 131 and the steering handle 10 is appropriately converted and transmitted to the vertically long double shaft 221 that is rotatably disposed at the lower end of the steering column 90. Is configured to do.

  The mechanical switching means 220 itself is not directly related to the present invention and will not be described in detail. However, if necessary, refer to Japanese Patent Application Laid-Open No. 2002-274421.

  The double shaft 221 associated with the mechanical switching means 220 is formed in a vertically long concentric shape by a rectilinear outer cylindrical shaft 222 and a turning inner shaft 223 that can be rotated independently of each other. The rectilinear outer cylinder shaft 222 is linked to a rectilinear rotation shaft 225 protruding outward from one side surface of the mission case 13 via a rectilinear link mechanism 224. On the other hand, the turning inner shaft 223 is linked to a turning rotation shaft 227 protruding outward from the other side surface of the transmission case 13 via a turning link mechanism 226.

  Here, the rectilinear rotation shaft 225 is for adjusting the inclination angle of the rotary swash plate 180 of the first hydraulic pump 150 in the rectilinear HST transmission mechanism 63. Functions as an adjustment unit that adjusts the output. The turning shaft 227 is for adjusting the inclination angle of the rotary swash plate 182 of the second hydraulic pump 152 in the turning HST transmission mechanism 64, and adjusts the shift output of the turning HST transmission mechanism 64. Functions as an adjustment unit.

  The linear link mechanism 224 includes a lateral support shaft 230 that is rotatably inserted into a support cylinder 229 fixed to the upper surface of the transmission case 13 via a bracket 228, and a linear advance that projects from the linear cylinder outer shaft 222. The straight relay rod 233 that connects the rotary arm 231 and the first straight swing arm 232 fixed to one end (right end in the embodiment) of the horizontal support shaft 230, and the other end of the horizontal support shaft 230 (the embodiment). In this case, a linear movement interlocking rod 236 that connects a linear movement second swing arm 234 fixed to the left end) and a linear operation arm 235 attached to the linear rotation shaft 225 is provided.

  One end portion (front end portion in the embodiment) of the rectilinear relay rod 233 is pivotally attached to a rectilinear pivot arm 231 on the rectilinear outer cylinder shaft 222 side by a longitudinal pivot pin 237. Yes. The other end portion (rear end portion in the embodiment) of the rectilinear relay rod 233 is pivoted to the first rectilinear swing arm 232 on the side support shaft 230 side via a pivot pin 238 that is laterally laterally oriented. It is worn.

  One end portion (upper end portion in the embodiment) of the linear advancement interlocking rod 236 is pivotally attached to the second advancement swing arm 234 on the side of the lateral support shaft 230 so as to be rotatable by a left and right laterally attached pivot pin 239. Yes. The other end portion (the lower end portion in the embodiment) of the rectilinear interlocking rod 236 is pivotally attached to a rectilinear operation arm 235 on the rectilinear pivot shaft 225 side via a pivot pin 240 which is front-rear and sideways. ing.

  When the main transmission lever 131 is tilted forward from the neutral position, the mechanical switching means 220 moves the outer straight shaft 222 and the straight turn arm 231 around the turn inner shaft 223 via the relay link mechanism 219. By rotating integrally in the direction of the arrow SA, the straight relay rod 233 is pulled forward (moved), the first straight swing arm 232, the lateral support shaft 230, and the second straight swing. The arm 234 rotates integrally in the direction of the arrow SB around the lateral support shaft 220.

  Then, the rectilinear second swing arm 234 pulls up the rectilinear interlocking rod 236 by the rotational movement in the direction of arrow SB, so that the rectilinear operation arm 235 and hence the rectilinear rotation shaft 225 are moved in the direction of the arrow SC (forward increase). It rotates in the speed direction (or reverse deceleration direction). As a result, the traveling machine body 1 performs the forward movement in proportion to the forward tilting operation amount of the main transmission lever 131.

  On the other hand, when the main transmission lever 131 is tilted backward from the neutral position, the mechanical switching means 220 moves the rectilinear outer cylindrical shaft 222 and the rectilinear rotation arm 231 in the direction of the arrow SD via the relay link mechanism 219. By rotating integrally, the rectilinear relay rod 233 moves backward, and the first rectilinear swing arm 232, the lateral support shaft 230, and the second rectilinear swing arm 234 are arrows opposite to the previous arrows. Rotates integrally in the SE direction.

  Then, the rectilinear second swing arm 234 pushes down the rectilinear interlocking rod 236 by pivoting movement in the arrow SE direction, so that the rectilinear operation arm 235 and hence the rectilinear pivot shaft 225 are moved in the arrow SF direction (reverse increase). It rotates in the speed direction (or forward deceleration direction). As a result, the traveling machine body 1 performs the reverse operation in proportion to the backward tilting operation amount of the main transmission lever 131.

  On the other hand, the turning link mechanism 226 includes a turning cylinder 241 that is rotatably fitted to a projecting portion of the lateral support shaft 230 from the support cylinder 229 and a turning turning arm that protrudes from the turning inner shaft 223. 242 and a pivoting relay rod 244 connecting the substantially rod-shaped first swinging arm 243 projecting from the rotating cylinder 241 and a second swinging arm 245 for pivoting projecting from the rotating cylinder 241. And a turning interlocking rod 247 that connects the turning operation arm 246 attached to the turning shaft 227 for turning.

  One end portion (the front end portion in the embodiment) of the turning relay rod 244 is pivotally attached to the turning arm 242 on the turning inner shaft 223 side so as to be turnable by a longitudinally attached pivot pin 248. . The other end portion (rear end portion in the embodiment) of the turning relay rod 244 pivots to the turning first swing arm 243 on the turning cylinder 241 side via a left and right laterally attached pivot pin 249. It is worn.

  One end portion (upper end portion in the embodiment) of the turning interlocking rod 247 is pivotally attached to the second swinging arm 245 for turning on the side of the turning cylinder 241 so as to be turnable by a pivoting pin 250 facing left and right laterally. Yes. The other end portion (the lower end portion in the embodiment) of the turning interlocking rod 247 is pivotally attached to the turning operation arm 246 on the turning turning shaft 227 side via a pivoting pin 251 that is oriented in the front-rear and lateral directions. ing.

  For example, when the steering handle 10 is rotated to the left with the main transmission lever 131 tilted forward, the mechanical switching means 220 is connected to the turning inner shaft 223 and the turning turning arm via the handle shaft 92. By rotating 242 integrally in the direction of the arrow TA, the turning relay rod 244 is pulled forward, and the turning first swing arm 243, the turning cylinder 241 and the turning second swing arm 245 are moved. It rotates integrally in the direction of arrow TB around the lateral support shaft 230.

  Then, the second swing arm 245 for swinging raises the interlocking interlocking rod 247 by the rotational movement in the arrow TB direction, so that the swing operation arm 246 and hence the pivot shaft 227 for swinging are moved in the direction of the arrow TC (forward leftward rotation). Rotate in the rotation direction). As a result, the traveling machine body 1 performs a left turn operation in proportion to the amount of leftward turning operation of the steering handle 10.

  In this case, the straight link mechanism 224 causes the straight rotation shaft 225 to move in the direction of the arrow SF (forward deceleration direction) in proportion to the amount of leftward rotation of the steering handle 10 by the action of the mechanical switching means 220. ), And the forward turning speed of the traveling machine body 1 is decelerated corresponding to the turning radius at that time.

  On the other hand, when the steering handle 10 is rotated to the right while the main transmission lever 131 is tilted forward, the mechanical switching means 220 is connected to the turning inner shaft 223 and the turning rotation via the handle shaft 92. By rotating the moving arm 242 integrally in the direction of the arrow TD, the turning relay rod 244 moves rearward, and the first turning arm 243 for turning, the turning cylinder 241 and the second turning arm for turning. 245 rotates integrally in the direction of arrow TE opposite to the previous direction.

  Then, the second swing arm 245 for turning pushes down the turning interlocking rod 247 by the turning movement in the direction of the arrow TE, so that the turning operation arm 246 and consequently the turning shaft 227 for turning is moved in the direction of the arrow TF (forward right) It turns in the turning direction. As a result, the traveling machine body 1 performs a right turn operation in proportion to the amount of rightward turning operation of the steering handle 10.

  Also in this case, the straight link mechanism 224 causes the straight rotation shaft 225 to move in the direction of arrow SF (forward deceleration) in proportion to the amount of rotation of the steering handle 10 in the right direction by the action of the mechanical switching means 220. The forward turning speed of the traveling machine body 1 is decelerated corresponding to the turning radius at that time.

  When the steering handle 10 is turned left and right with the main transmission lever 131 tilted rearward, the operations of the turning link mechanism 226 and the rectilinear link mechanism 224 are opposite to those described above. In other words, the operations of both link mechanisms 226 and 224 at the time of forward left turn are the same as those at the time of reverse right turn, while the operations of both link mechanisms 226 and 224 at the time of forward right turn are the same as those at the time of reverse left turn. Is set to

(6). Next, the various operation means arranged in the control unit 9 will be described with reference mainly to FIGS. 10 and 11.

  A vertically long steering column 90 and a front panel body 91 extending horizontally from the steering column 90 are disposed in front of the control seat 11 in the control unit 9. A round steering handle 10 for changing the traveling (turning) direction and turning speed of the traveling machine body 1 is attached to a handle shaft 92 (see FIGS. 9 and 11) protruding upward from the steering column 90. ing.

  When the turning operation position of the steering handle 10 is within the first minute turning angle range from the neutral position N (also referred to as the straight running position) to the left and right, that is, in the neutral region NE shown in FIG. The swing valve 202 has almost no function (switching operation), and the traveling machine body 1 is configured not to perform a swing operation in proportion to the amount of rotation of the steering handle 10 (maintain a so-called play state). Yes.

  When the turning operation position of the steering handle 10 is in the normal turning areas LT and RT (see FIG. 11) outside the neutral area N, the manual turning valve 202 is switched and the traveling machine body 1 is steered. A turning operation is performed in proportion to the amount of turning operation of the handle 10. Needless to say, the steering handle 10 is automatically returned to the neutral position N when the hand is released from the steering handle 10.

  In the embodiment, the angle range of the neutral region NE is set to a size of about 15 ° to the left and right (a total of 30 °) across the neutral position N. Further, the pivotable range of the steering handle 10 is set to a size of about 135 ° to the left and right across the neutral position N (see FIG. 11).

  In the steering column 90, the rotation position sensor 93 as a rotation detection means for detecting the rotation operation position (or the rotation operation amount) of the steering handle 10 and the steering handle 10 are in the neutral position N. Is provided in association with the handle shaft 92 (see FIG. 12). The rotation position sensor 93 of the embodiment is of a rotary encoder type or a rotary potentiometer type.

  A center panel body 95 having a liquid crystal display device 96 and the like is disposed inside a substantially annular handle wheel portion 94 in the steering handle 10. Since the center panel body 95 is fixed only to the steering column 90 and is not connected to the steering handle 10, even if the steering handle 10 is rotated, the center panel body 95 and thus the liquid crystal display device 96 are also operated. Does not move, and the screen is always easy to see from the operator.

  A steering switch 100 as a manual input means is provided on the upper surface of the grip portion on one of the left and right sides (right side in the embodiment) of the handle wheel portion 94. The steering switch 100 is a so-called cross-direction switch configured to be operable in the front-rear and left-right directions (cross direction).

  The steering switch 100 according to the embodiment forcibly lifts the cutting unit 3 to a height position necessary for changing the direction of the traveling machine body 1 at the headland (binge) while pushing the steering switch 100 forward. And a forcible setting operation for forcibly lowering the cutting unit 3 to a predetermined cutting height position is performed while pushing backward.

  While the steering switch 100 is being pushed left or right, the electromagnetic automatic steering valve 203 (see FIGS. 8 and 12) in the hydraulic circuit 190 is activated by the excitation of the left or right steering solenoids 204 and 205. And it is comprised so that the traveling body 1 may carry out the fine turning (fine correction) to the left or the right.

  The steering switch 100 and the steering handle 10 are configured to be operated independently of each other (can be operated separately). In addition, the turning operation amount of the traveling machine body 1 with respect to the unit operation amount of the steering handle 10 is set to be significantly larger than the turning operation amount of the traveling machine body 1 with respect to the unit operation amount of the steering switch 100.

  Therefore, if both the steering handle 10 and the steering switch 100 are operated, both the manual swing valve 202 and the electromagnetic automatic steering valve 203 in the hydraulic circuit 190 are switched to rotate the steering handle 10. The turning operation of the traveling machine body 1 in the left-right direction is executed by the sum of the turning operation amount corresponding to the operation amount and the minute turning operation amount corresponding to the pressing operation amount of the steering switch 100. In other words, the traveling machine body 1 turns larger or smaller than the turning operation amount corresponding to the turning operation amount of the steering handle 10 by the minute turning operation amount corresponding to the pressing operation amount of the steering switch 100. is there.

  With this configuration, when the steering switch 100 is pushed left or right when the steering operation position of the steering handle 10 is in the neutral region NE, the traveling machine body 1 is turned left or right accordingly. Since the micro-turning (fine correction) is performed, the adjusting operation for causing the weeding body 17 of the cutting unit 3 to follow the planted culm C row in the field can be executed by the pushing operation to the left and right.

  Further, if the steering switch 100 is operated to the left or right when the turning operation position of the steering handle 10 is in the normal turning areas LT and RT (when it is out of the neutral area NE), the steering handle 10 The turning operation amount in the left-right direction of the traveling machine body 1 can be executed by supplementing the turning operation amount in accordance with the turning operation amount with the minute turning operation amount in accordance with the pressing operation amount of the steering switch 100. That is, the adjustment / correction of the turning motion amount of the traveling machine body 1 can be performed reliably and easily without finely adding or turning back the steering handle 10 during the turning operation. Therefore, it is very easy for the operator to adjust the traveling direction of the traveling machine body 1 and the operability is good.

  Although details will be described later, in the embodiment, the cutting unit 3 is located at a position lower than the non-cutting height position H1, or at least one of the three culm passing sensors 54 detects the presence of a conveying culm. In the state, the steering switch 100 is configured to allow left-right operation.

  In this case, the non-cutting height position H1 is the position of the cutting unit 3 when traveling on the road and the like, and the set cutting height position H0 (the planted grain culm in the field) preset by the cutting height setting dial 105 It is a position higher than (the position of the cutting part 3 when cutting C). Accordingly, the fact that the cutting unit 3 is at a position lower than the non-cutting height position H1 corresponds to a state in which the cutting unit 3 is lowered to, for example, the set cutting height position H0 or the like for the cutting and threshing operation.

  Further, in a state where the cutting unit 3 has reached the non-cutting height position H1 and all of the three culm passing sensors 54 detect the absence of the transported culm (not sensing the transported culm), The operation of the steering switch 100 in the left-right direction is restricted (not functioned).

  Here, restricting the left / right operation of the steering switch 100 (does not function) means that the electromagnetic automatic steering valve 203 in the hydraulic circuit 190 is not switched even if the steering switch 100 is operated to the left or right. And an expression (meaning) including disabling the operation of the steering switch 100 in the left-right direction. In the embodiment, a configuration is adopted in which the electromagnetic steering valve 203 in the hydraulic circuit 190 is not switched and maintained in a neutral state.

  On the other hand, the operation of the steering switch 100 in the front-rear direction is also permitted only when the turning operation position of the steering handle 10 is in the neutral region NE. That is, only when the steering operation position of the steering handle 10 is in the neutral region NE, the forcible lift operation or the forcible set operation is executed by the operation of the steering switch 100 in the front-rear direction. Needless to say, when the finger is released from the steering switch 100, the steering switch 100 automatically returns to its neutral position.

  Note that a horn switch 103 for performing an operation of sounding the horn 102 (horn, see FIG. 12) is provided on the upper surface of the grip portion on the other side (left side in the embodiment) of the handle wheel portion 94.

  On the left and right front panel bodies 91, a plurality of various operation switches and setting dials are arranged. For example, an automatic cutting height switch 104, a cutting height setting dial 105, a sorting adjustment dial 106, an automatic steering switch 107, and the like are disposed on the left front panel body 91. The automatic cutting height switch 104 is for operating on / off of automatic cutting height control for maintaining the cutting unit 3 at a predetermined cutting height position. The cutting height setting dial 105 is used to set and operate the cutting height position during automatic cutting height control. The sorting adjustment dial 106 is for adjusting the sorting state of the grains in the sorting device 20. The automatic steering switch 107 is for operating on / off of the automatic steering control that causes the traveling machine body 1 to travel along the row of planted culms C in the field.

  On the right front panel body 91, an automobile speed switch 108, an automatic horizontal switch 109, an inclination setting dial 110, an automatic handling depth switch 111, and the like are arranged. The vehicle speed switch 108 is for operating on / off of vehicle speed control for decelerating the vehicle speed when the engine 12 is overloaded and maintaining the rotational drive of the mowing unit 3 and the threshing unit 6 constant. The automatic horizontal switch 109 is for operating on / off of automatic horizontal control for maintaining the traveling machine body 1 in a horizontal horizontal posture. The tilt setting dial 110 is for setting and operating the left and right tilt angle of the traveling machine body 1. The automatic handling depth switch 111 is for operating on / off of the automatic handling depth control for maintaining the handling depth position of the harvested cereal mash relative to the threshing unit 6 at a predetermined position.

  Each of the switches 104, 107, 108, 109, and 111 is a push switch (momentary switch) that generates one ON pulse signal when pressed once, and is of a non-locking type. When the switch 104, 107, 108, 109, 111 is pressed once to enter the switch, the switch lamps 114, 117, 118, 119, 121 above it are lit, and the switch is pressed again to turn off the switch. In this case, the switch lamps 114, 117, 118, 119, 121 are configured to be turned off.

  On one side of the control seat 11 (left side in the embodiment), a side panel body 130 that is long in the front-rear direction is disposed. On the side panel body 130, a main transmission lever 131, an auxiliary transmission lever 132, and a clutch lever 133 are arranged in this order from the front.

  The main speed change lever 131 is used for steplessly changing the forward, stop, reverse, and vehicle speed of the traveling machine body 1 and can be tilted forward and backward along a crank-shaped guide groove 134 in the side panel body 130. It is configured.

  When the main transmission lever 131 is tilted forward from a neutral position (stop position) in a substantially vertical posture, the traveling machine body 1 moves forward. The forward speed of the traveling machine body 1 increases as the tilt angle of the main transmission lever 131 forward increases. Conversely, when the main transmission lever 131 is tilted backward from the neutral position, the traveling machine body 1 moves backward. The reverse speed of the traveling machine body 1 increases as the tilt angle of the main transmission lever 131 to the rear increases.

  On the upper surface of the grip portion of the main transmission lever 131, a cutting lift switch 141 for manually moving the cutting portion 3 up and down is disposed. The mowing lift switch 141 is a rocker (seesaw) switch that can be rotated around a support shaft (not shown) located in the middle of the longitudinal (front-rear) direction. The cutting lift switch 141 is configured such that when the rear end portion is pushed, the hydraulic cylinder 4 extends to raise the cutting portion 3, and when the front end portion is pushed, the hydraulic cylinder 4 is shortened to lower the cutting portion 3. ing. In the cutting lift switch 141, the amount of expansion / contraction of the hydraulic cylinder 4 (the amount of lifting of the cutting part 3) increases proportionally when the pushing operation time of the front and rear ends is long, and is neutral when the fingers are released from the front and rear ends. It is configured to return to the position.

  The sub-transmission lever 132 is used to change and operate the sub-transmission mechanism 85 of the hydraulic drive device 62 according to the working state, and to set and hold the output and the rotational speed of the hydraulic drive device 62 within a predetermined range.

  In the embodiment, the output and the rotational speed of the hydraulic drive device 62 are switched to two steps of a low-speed operation mode and a high-speed travel mode by operating the auxiliary transmission lever 132. Here, the work mode is a mode suitable for low-speed travel such as during farm work, and the travel mode is a mode suitable for high-speed travel such as during road travel.

  The sub-shift lever 132 is configured to be able to tilt forward and backward, so that the travel mode is selected when the sub-shift lever 132 is tilted forward from a substantially vertical neutral position, and the work mode is selected when the tilt is operated backward. Is set.

  The clutch lever 133 is a combination of a lever for power cutting operation of the reaping portion 3 and a lever for power cutting operation of the threshing portion 6, and is substantially L-shaped in plan view in the side panel 130. It is configured to be tiltable in the left and right and front and rear directions along the guide groove 135.

  When the clutch lever 133 of the embodiment is tilted to the left end position of the left and right groove portions 135a in the guide groove 135, both the cutting clutch 82 and the threshing clutch 71 (see FIG. 6) are in a disconnected state, and the right end position (front and rear groove portions 135b) of the left and right groove portions 135a. The threshing clutch 71 alone is engaged when tilted to the rear end position), and the clutches 82 and 71 are both engaged when tilted to the front end position of the front and rear groove 135b.

(7). Configuration of Control Means Next, a configuration for executing the alignment operation and automatic steering control of the traveling machine body 1 will be described with reference to FIG.

  Although not shown in detail, a controller 140 such as a microcomputer as a control means includes a central processing unit (CPU) for executing various arithmetic processes and controls, and a read-only memory (for storing control programs and data). ROM), read / write memory (RAM) as needed to temporarily store control programs and data, clocks as timer functions, and input / output interfaces for exchanging data with input / output devices (sensors, actuators, etc.) (Not shown).

  The input interface of the controller 140 includes a rotation position sensor 93 as a rotation detection means for the steering handle 10, a straight advance sensor 99, a steering switch 100 as a manual input means, a horn switch 103, a main transmission lever 131, and a cutting lift switch. 141, auxiliary transmission lever 132, clutch lever 133, automatic cutting height switch 104, cutting height setting dial 105, sorting adjustment dial 106, automatic steering switch 107, automobile speed switch 108, automatic horizontal switch 109, inclination setting dial 110 , Automatic handling depth switch 111, switch lamps 114, 117, 118, 119, 121 corresponding to these switches 104, 107, 108, 109, 111, a power switch 136 for turning on and off the entire combine power, Left and right operation Sensor 50,51,3 one culms passage sensor 54, the left and right ultrasonic sensor 56, and, like the lifting position sensor 57 are connected.

  On the other hand, on the output interface of the controller 140, left and right steering solenoids 204 and 205 for switching the electromagnetic automatic steering valve 203, a cutting drive circuit 137 for driving the cutting clutch actuator, and a threshing cylinder 208 are driven. A threshing drive circuit 138 for driving, a lifting drive circuit 139 for driving the hydraulic cylinder 4, a liquid crystal display device 96, a horn 102 (horn), and the like are connected to each other.

(8). First Embodiment of Steering Switch Operation Control Next, a first embodiment of steering switch operation control will be described with reference to the flowchart shown in FIG.

  First, following the start, it is determined whether or not the steering switch 100 has been operated in the left-right direction (step S1).

  When the steering switch 100 is not operated in the left-right direction (S1: NO), the process returns as it is. When the steering switch 100 is operated in the left-right direction (S1: YES), then, from the detection information of the lift position sensor 57, the cutting unit 3 sets the cutting height position H0 preset by the cutting height setting dial 105. It is determined whether or not a higher non-cutting height position H1 has been reached (step S2).

  When the cutting unit 3 has not reached the non-cutting height position H1 (S2: NO), when the cutting unit 3 is at a position lower than the non-cutting height position H1, that is, the cutting unit for cutting and threshing work. 3 is lowered to the set cutting height position H0 or the like, for example, and then the electromagnetic automatic steering valve 203 in the hydraulic circuit 190 is automatically switched to turn the traveling machine body 1 slightly left and right. The alignment operation is executed (step S4), and then the process returns.

  When the cutting unit 3 has reached the non-cutting height position H1 (S2: YES), whether or not one of the three culm passing sensors 54 has detected culm, in other words, Then, it is determined whether or not the presence of cereals is sensed (step S3).

  When all the three culm passing sensors 54 detect the absence of culm (not sensing the culm) (S3: NO), the cutting unit 3 has already reached the non-cutting height position H1. Therefore, this corresponds to a non-agricultural work state such as traveling on the road or over a fence, that is, when no cutting work is performed. Therefore, in this case, the steering switch 100 returns without executing the minute turning motion (alignment operation) of the traveling machine body 1.

  When at least one of the three culm passing sensors 54 detects the presence of the culm (S3: YES), then the electromagnetic automatic steering valve 203 in the hydraulic circuit 190 is automatically switched and operated. An alignment operation for slightly turning the traveling machine body 1 to the left and right is executed (step S4), and then the process returns.

  If the control is performed as described above, the left and right sides of the steering switch 100 can be determined as long as the cutting unit 3 reaches the non-cutting height position H1 and all the three culm passing sensors 54 detect the absence of the culm. Since the operation of the direction is restricted (does not function), even if the steering switch 100 is mistakenly operated in the left-right direction during non-farm work such as running on the road, the steering switch 100 performs a slight turning motion (strip). Alignment operation) is not executed. For this reason, it is possible to reduce the risk that the traveling machine body 1 turns in an unexpected direction against the operator's intention (such as meandering or turning left and right more than expected), and the traveling safety during non-farm work is improved.

  Further, if the cutting unit 3 is at a position lower than the non-cutting height position H1 or if any one of the three culm passing sensors 54 detects the culm, the left and right of the steering switch 100 Since operation in the direction is allowed, for example, even if there is no dedicated switching operation means (such as a switch or a lever) for selectively switching between a state where the steering switch 100 can function and a state where the steering switch 100 does not function, In the course of a series of operations when performing the threshing operation, the steering switch 100 can be automatically switched to a state where it can function. Therefore, the operability of the steering switch 100 considering the prevention of erroneous operation / operation is greatly improved.

(9). Second Embodiment of Steering Switch Operation Control Next, a second embodiment of steering switch operation control will be described with reference to the flowchart shown in FIG.

  In 2nd Embodiment, it replaces with the grain pass sensor 54, and the point which employ | adopts the left and right steering sensors 50 and 51 for planted grain straw detection means as a grain straw detection means, and the thing of 1st Embodiment. It is different. Other configurations are the same as those of the first embodiment.

  In the steering switch operation control in the second embodiment, the functions exhibited by the grain pass sensor 54 in the first embodiment are merely replaced by the left and right steering sensors 50 and 51.

  That is, following the start, it is determined whether or not the steering switch 100 has been operated in the left-right direction (step P1).

  When the steering switch 100 is not operated in the left-right direction (P1: NO), the process returns as it is. When the steering switch 100 is operated in the left-right direction (P1: YES), then, from the detection information of the lift position sensor 57, the cutting unit 3 sets the cutting height position H0 set in advance by the cutting height setting dial 105. It is determined whether or not a higher non-cutting height position H1 has been reached (step P2).

  When the cutting unit 3 has not reached the non-cutting height position H1 (P2: NO), when the cutting unit 3 is at a position lower than the non-cutting height position H1, that is, the cutting unit for cutting and threshing work. 3 is lowered to the set cutting height position H0 or the like, for example, and then the electromagnetic automatic steering valve 203 in the hydraulic circuit 190 is automatically switched and the traveling body 1 is turned slightly to the left and right. The alignment operation is executed (step S4), and then the process returns.

  When the cutting unit 3 has reached the non-cutting height position H1 (P2: YES), it is then determined whether or not one of the left and right steering sensors 50 and 51 has detected the presence of a culm. (Step P3).

  When both the left and right steering sensors 50 and 51 detect that there is no culm (P3: NO), the mowing unit 3 has already reached the non-cutting height position H1, so that it travels on the road or crosses the heel. This corresponds to a non-agricultural work state such as when no cutting work is performed. Therefore, in this case, the steering switch 100 returns without executing the minute turning motion (alignment operation) of the traveling machine body 1.

  If any of the left and right steering sensors 50 and 51 detects the presence of a candy (P3: YES), then the electromagnetic automatic steering valve 203 in the hydraulic circuit 190 is automatically switched. Then, the alignment operation for slightly turning the traveling machine body 1 to the left and right is executed (step S4), and then the process returns.

  Even when the control is performed as described above, the same effects as those of the first embodiment can be obtained.

(10). Others The present invention is not limited to the above-described embodiment, and can be embodied in various forms. For example, the steering switch 100 as the manual operation means is not limited to the cross-type switch and may be a two-way type switch as long as it is for an operation that slightly turns (finely corrects) the traveling machine body 1 to the left or right. May be.

  Further, the shape of the handle wheel portion in the steering handle is not limited to the round shape (annular shape) as described above, and a U-shape shape as shown in FIG. In the steering handle 10 'shown in FIG. 15, a steering switch 100' serving as manual input means is provided on the upper surface of the grip portion on the left and right sides (right side in FIG. 15) of the U-shaped handle wheel portion 94 '. On the other hand (on the left side in FIG. 15), a horn switch 103 ′ is provided on the upper surface of the grip portion. The steering switch 100 'is a two-way switch configured to be operable in the left-right direction. In FIG. 15, the center panel body as in the above-described embodiment is not arranged inside the handle wheel portion 94 ′.

  In addition, the structure of each part is not limited to embodiment of illustration, A various change is possible in the range which does not deviate from the meaning of this invention.

It is a side view of a combine. It is a top view of a combine. It is a schematic front view which shows the arrangement | positioning relationship of each apparatus in a cutting part. It is a schematic plan view of the front part in a cutting part. It is front explanatory drawing of a traveling machine body front part. It is a skeleton figure of the power transmission system in a combine. It is a skeleton figure which shows the power transmission system in a mission case. It is a hydraulic circuit diagram of a combine. It is explanatory drawing which shows typically the connection relation of a main speed-change lever, a steering handle, and a hydraulic drive means. It is a top view of a control part. It is an enlarged plan view of a steering handle. It is a functional block diagram of a controller. It is a flowchart explaining 1st Embodiment of steering switch operation control. It is a flowchart explaining 2nd Embodiment of steering switch operation control. It is an enlarged plan view which shows another example of a steering handle.

Explanation of symbols

N Neutral position NE Neutral area LT, RT Normal turning area 1 Traveling machine body 2 Traveling crawler 3 as traveling part 3 Cutting part 4 Hydraulic cylinder 6 Threshing part 9 Steering part 10 Steering handle 50, 51 Steering sensor 54 Grain pass sensor 56 Ultrasonic sensor 57 Elevating position sensor 62 Hydraulic drive device 63 Traveling HST transmission mechanism 64 Turning HST transmission mechanism 92 Handle shaft 93 Rotation position sensor 94 as rotation detection means Handle wheel unit 100 As manual input means Steering switch 131 Main transmission lever 132 Sub transmission lever 133 Clutch lever 139 Lift drive circuit 140 Controller

Claims (2)

While being configured to transmit the power from the engine mounted on the traveling machine body to the cutting part and the traveling part that are mounted on the front part of the traveling machine body so as to be adjustable in elevation, the traveling direction of the traveling machine body is A steering handle for changing operation is provided, and a handle wheel portion of the steering handle is a combine having manual input means for finely adjusting a traveling direction of the traveling machine body,
The reaping part is provided with cereal detection means for detecting the presence or absence of cereal in the reaping part,
The operation of the manual input means is restricted in a state where the cutting part is at a non-cutting height position higher than a preset setting cutting height position and the husk detection means detects no husk. The combine characterized by being comprised as follows. While being configured to transmit the power from the engine mounted on the traveling machine body to the cutting part and the traveling part that are mounted on the front part of the traveling machine body so as to be adjustable in elevation, the traveling direction of the traveling machine body is A steering handle for changing operation is provided, and a handle wheel portion of the steering handle is a combine having manual input means for finely adjusting a traveling direction of the traveling machine body,
The reaping part is provided with cereal detection means for detecting the presence or absence of cereal in the reaping part,
It is configured to allow the manual input means to be operated in a state where the cutting part is at a position lower than the non-cutting height position or the culm detection means detects the presence of the culm. Combine that features.

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