JP4548579B2 - Combine - Google Patents

Description

  The present invention relates to a traveling vehicle such as a combine.

  For example, as a work vehicle using a crawler as a traveling means, a conventional technique will be described taking an agricultural combine as an example. The combine has an endless belt-like crawler, and can run freely even in a soft field such as paddy fields to enable agricultural work such as mowing.

  The combine is equipped with an engine as a power source, and the power generated by the engine is used for traveling, harvesting, threshing, etc. of the combine. The crawler drives the engine power by shifting it with a traveling transmission device. The traveling transmission is composed of a hydrostatic continuously variable transmission, a gear train mechanical transmission means, a differential gear device, a clutch means, a brake means, etc., and a slow turning mechanism and a brake turning mechanism by operating a steering lever. A mechanism for selecting a quick turning mechanism is provided.

In order to improve the turning performance, the traveling has a configuration in which the braking pressure can be changed with a manual dial so that the braking pressure of the traveling drive body inside the turning can be changed and adjusted according to the inclination angle of the steering lever. A vehicle is known (Japanese Patent Laid-Open No. 2000-226256).
JP 2000-226256 A

  In the invention described in Japanese Patent Laid-Open No. 2000-226256, a wetland switch is turned on during traveling in a traveling mode suitable for wetland traveling (sometimes referred to as a wetland mode), and manual operation is performed to optimize the turning performance in that case. The brake pressure of the turning clutch of the traveling device was adjusted with the dial. Also, when driving on relatively hard fields other than wet fields (sometimes referred to as standard mode), turn off the wet field switch and adjust the braking pressure of the turning clutch using the manual dial to optimize turning performance. Was.

As described above, conventionally, the braking pressure of the turning clutch has been adjusted by the manual dial independently during traveling in the wet field and during traveling in other fields.
For this reason, when the braking pressure of the turning clutch set by the manual dial is too small, the turning radius becomes larger than expected by the operator, and it is necessary to make adjustment again with the manual dial each time.

  In wet field mode driving, the turning performance is ensured by lowering the braking pressure of the turning clutch than in standard mode driving, but depending on the adjustment amount of the two manual dials, When traveling, the braking pressure of the turning clutch was even higher than when traveling in the standard mode.

Accordingly, an object of the present invention is to provide a combine having a steering mechanism that can appropriately adjust the braking pressure of the turning clutch when traveling in the standard mode and the braking pressure of the turning clutch when traveling in the wet paddy mode. is there.

According to the first aspect of the present invention, the engine provided in the vehicle body (2) and the power obtained by shifting the driving force from the engine are transmitted, and the vehicle can be turned left and right in the traveling direction. traveling drive body (3), said travel driving body (3) steering operation member for adjusting a steering operation (21), and shifting the driving force transmitted to the traveling drive body (3) from the engine, the main The rotational speed of the traveling drive body ( 3 ) inside the turn is braked according to the steering operation amount of the hydraulic continuously variable transmission (18), auxiliary transmission (24), and steering operation tool ( 21 ) for the transmission. traveling with said running drive member and the turning clutch adjusted by pressure changing turning performance (82) straight clutch (81) for driving the left and right traveling drive body (3,3) at a constant speed during straight ahead travel (3) A cutting device provided on the front side of the mission device (14) and the traveling drive body (3) And (9), in combined with a threshing device (10) and for threshing the culms of reaped by該刈winding device (9), the traveling drive of the turning inner side (3) is reduced to zero or near zero rotate during turning A mode changeover switch ( 104 ) capable of setting a travel mode between a standard mode and a wet paddy mode in which the rotational speed of the travel drive body ( 3 ) inside the turn during the turn is set higher than the set value of the standard mode; the braking pressure of Shitsuden mode pivoting clutch (82) with changing each said threshing apparatus (10) of the threshing clutch adjustable adjustment means the braking pressure of Shitsuden mode turning the clutch when the input (82) (68, 69 ) and the lower limit value of the adjustment range of the braking pressure of the swing clutch ( 82 ) in the standard mode when the steering operation tool ( 21 ) is operated with the maximum steering operation amount. The control value is the same or substantially the same as the reference value between the upper limit value and the lower limit value of the braking pressure adjustment range of the swing clutch ( 82 ) , and the steering operation tool (21) is operated with the maximum steering operation amount. controller the straight clutch the lower limit of the adjustment range of the braking pressure (81) is the same or substantially the same as the pressure is disconnected Shitsuden mode pivoting clutch (82) of Rutoki and (100) is provided, the traveling The transmission device (14) includes a main body case (12) in which a hydraulic continuously variable transmission (18) and a sub-transmission (24) for the main transmission are provided, and a hydraulic non-transmission transmitted from the engine. An output shaft (17) for outputting the power shifted by the step transmission (18), a wide transmission gear (26) provided on the output shaft (17), and a power from the wide transmission gear (26) Of countershaft (60) to which is transmitted The input gear (61), the input shaft (27) to which the cutting output shaft (65) to the cutting device (9) is engaged and the power is input to the auxiliary transmission (24), and the input shaft A transmission gear (62) that is provided between the auxiliary transmission (24) and the cutting output shaft (65) of (27) and that transmits power from the counter gear (61); An oil seal (66) is provided on the input shaft (27) between the device (24) and the transmission gear (62), and the oil seal (66) causes the output shaft (18) of the hydraulic continuously variable transmission (18) ( 17) is a combine in which a hydraulic tank (67) provided with the wide transmission gear (26), the counter gear (61) and the transmission gear (62) is provided independently of the main body case (12). .

According to the first aspect of the present invention, the lower limit value of the adjustment range of the braking pressure of the swing clutch ( 82 ) in the standard mode when operated with the maximum steering operation amount of the steering operation tool ( 21 ) Since the braking pressure of the turning clutch ( 82 ) is the same as or substantially equal to the braking pressure of the mode reference turning clutch ( 82 ) , the adjustment range of the braking force of the turning clutch ( 82 ) is widened in an appropriate range, and the operability and condition adaptability are improved.

Further , the lower limit value of the adjustment range of the braking pressure of the swing clutch ( 82 ) when the steering operation tool ( 21 ) is operated with the maximum steering operation amount during running in the wet paddy mode is the pressure at which the straight clutch ( 81 ) is disengaged. Therefore, in the wet paddy mode, the swing clutch ( 82 ) starts operating at a pressure that cuts off the straight clutch ( 81 ) . For this reason, since the vehicle turns only at a relatively weak pressure when traveling in the wet paddy mode, the turning steerability in the wet paddy is ensured.

Furthermore, when the threshing clutch of the threshing device (10) is turned on, the brake pressure can be adjusted in the field work in the wet paddy mode, so that the field adaptability and the traveling performance are improved.
  Further, an oil seal (66) is provided on the input shaft (27) side which is an input portion to the main body of the traveling mission device (14), and the output shaft (17), the wide transmission gear (26), and the counter shaft (60). The hydraulic tank (67) having the counter gear (61) and the transmission gear (62) is an oil tank completely independent of the main body case (12) of the traveling mission device (14), so that It is not necessary to prepare an oil passage provided in the central shaft portion of the mission input shaft (27), and the cutting output shaft (65) can be lubricated with the oil in the hydraulic tank (67). Therefore, the entire traveling mission device (14) can be manufactured at a relatively low cost.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a left side view of the combine of the present invention.
As shown in FIG. 1, a traveling device body 4 having a pair of left and right traveling devices (hereinafter referred to as traveling crawlers) 3 traveling on the soil surface is disposed on the lower side of the body frame 2 of the combine 1. A cutting device 9 having a weed pod 8 is provided on the front end side of 2. The reaping device 9 is supported by the reaping device support frame 7 that moves up and down around the upper fulcrum of the vehicle body frame 2, so that the operator boarding the combine 1 tilts the steering lever 21 of the cockpit 20 back and forth. It is the structure which moves up and down with the reaping device support frame 7 by operating.

  Above the body frame 2, a threshing device 10 that takes over and transports cereals that are conveyed from the reaping device 9, and a grain tank 13 that temporarily stores grains threshed and selected by the threshing device 10. The auger 15 is connected to the rear part of the grain tank 13 and the grains in the grain tank 13 are discharged to the outside of the combine 1.

  That is, in the combine 1, the operator operates the main transmission HST lever 23 and the auxiliary transmission lever 22 at the cockpit 20 to drive the power of the engine (not shown) for the main transmission in the traveling transmission case 12 shown in FIG. 2. The speed is changed via the HST 18 and the gear speed changing means of the auxiliary transmission 24, and is transmitted to the left and right traveling crawlers 3 and 3 to travel at an arbitrary speed.

  Further, the combine 1 can travel in various turns by the operator tilting the steering lever 21 left and right in the cockpit 20. That is, when the steering lever 21 is tilted in a direction to turn the combine 1, the side clutch 44 and the turning clutch 82 in the traveling mission case 12 shown in FIG. 2 are operated, and the left and right crawler drive sprockets 16L are operated. , 16R is selectively transmitted to the left and right traveling crawlers 3 and 3 so that the traveling direction is changed by giving a speed difference.

  FIG. 2 shows a cross-sectional view of the traveling mission device 14 of the combine 1 according to the present embodiment. FIG. 3 shows a relationship diagram of the rotation speed of the gear of the differential gear device. FIG. 4 shows an enlarged view of the clutch shaft 70 portion.

  The traveling transmission device 14 is a traveling transmission basic comprising the output shaft 17, the transmission input shaft 27, the mission counter shaft 33, the side clutch shaft 41, and the wheel shaft 11 of the hydraulic continuously variable transmission (traveling HST) 18 shown in FIG. The transmission system includes a traveling transmission differential transmission system (auxiliary transmission system) including a clutch shaft 70 and a differential gear mechanism support shaft 50.

First, the traveling transmission basic transmission system of the traveling mission apparatus 14 will be described mainly with reference to FIG.
A rotational driving force from an engine (not shown) is transmitted to the traveling HST 18 so that forward / reverse switching and variable speed rotational power are output from the output shaft 17. The main transmission lever 23 is configured to be capable of switching between increasing / decreasing shifting and forward / reverse (forward / reverse switching) of the traveling HST 18.

  Then, the steering lever 21 is operated to shift the “on” / “off” of the side clutch 41 described later and the differential gear device 6 to perform a turning operation.

  In the traveling mission case 12, an auxiliary transmission 24, a side clutch device 25, and a differential gear device 6 are provided. The left and right wheel shafts 11L, 11R on the lower transmission side of these devices are connected via drive sprockets 16L, 16R. Thus, the left and right traveling crawlers 3 and 3 are driven.

  The power from the wide transmission gear 26 of the output shaft 17 of the traveling HST 18 is transmitted to the counter gear 61 of the HST counter shaft 60, and the power is transmitted from the counter gear 61 to the transmission gear 62 on the transmission input shaft 27 of the auxiliary transmission 24. Be transmitted.

  The large gear 28, the middle gear 29, the small gear 30, and the large transmission gear 34, the medium shifting gear 35, and the small transmission gear provided on the transmission input shaft 27 of the auxiliary transmission 24 are integrally provided. 36. Gears 28 to 30 integrally provided on the mission input shaft 27 are configured to be slidable in the axial direction of the mission input shaft 27 by operation of the auxiliary transmission lever 22 so as to be capable of shifting. The transmission input shaft 27 extends from the traveling mission case 12 to the outer side, and a cutting transmission pulley (not shown) is pivotally attached to the rotating power of the cutting device 9 and the like to rotate the rotating power synchronized with the vehicle speed. The configuration is such that input is possible.

  The mission counter shaft 33 is mounted on the lower transmission side of the mission input shaft 27, and a large transmission gear 34, a shifting gear 35, a small transmission gear 36, and a transmission gear 37 are respectively attached thereto. The gears 34 to 37 of the mission counter shaft 33 do not move, and the large gear 28, the middle gear 29, and the small gear 30 that are integrally provided on the mission input shaft 27 slide with a shifter (not shown). The transmission large gear 34 meshes with the small gear 30 of the mission input shaft 27, the shifting gear 35 meshes with the middle gear 29 of the mission input shaft 27, and the transmission small gear 36 meshes with the large gear 28 of the mission input shaft 27. Engage with each other. Further, the transmission gear 37 is always meshed with the center gear 40 of the side clutch device 25.

  The side clutch device 25 is integrally provided with a side clutch shaft 41 that extends to the left and right with the center gear 40 as a substantial center. Sleeves 42L and 42R are loosely fitted on the side clutch shaft 41, and the center gear 40 is provided with claws 40bL and 40bR to which the clutch gears 43L and 43R can be engaged and released. The clutch gears 43L and 43R are integrally provided with the sleeves 42L and 42R.

  Since the clutch gears 43L and 43R are always meshed with the transmission gears 64L and 64R that are loosely fitted to the reduction shaft 63, the power from the clutch gears 43L and 43R passes through the gears 63aL and 63aR from the transmission gears 64L and 64R. Is transmitted to the wheel shaft gears 48L and 48R, transmitted from the wheel shaft gears 48L and 48R to the left and right traveling crawlers 3 and 3 from the drive sprockets 16L and 16R via the wheel shafts 11L and 11R.

  The configurations composed of the clutch gears 43L and 43R meshed in the claw clutch type and the claw portions 40bL and 40bR of the center gear 40 will be referred to as side clutches 44L and 44R, respectively.

  Further, springs 46L and 46R are provided between the sleeves 42L and 42R and the traveling mission case 12 via bearing spacers 45L and 45R, respectively, and the sleeves 42L and 42R and the clutch gears 43L and 43R are always provided by the springs 46L and 46R. The center gear 40 is biased. And, when turning, the shifter 47L, 47R is operated by the hydraulic pressure, and it can move in the direction to overcome the urging force of the corresponding spring 46L, 46R. Thereby, the side clutch 44L or 44R inside the turning is disengaged.

  Since the shifters 47L and 47R do not operate during straight traveling and the side clutches 44L and 44R are both engaged, the left and right traveling crawlers 3 and 3 rotate at a constant speed through a transmission path described later. Further, by operating the steering lever 21 in a desired turning direction, the shifter 47L or 47R is operated, and the engagement and release of the side clutch 44L or 44R inside the turning are selected.

  The outer peripheral gear 40 a of the center gear 40 is always meshed with a gear 72 a of a cylindrical rotating body 72 that is loosely fitted on the clutch shaft 70. A rectilinear clutch 81 comprising a multi-plate friction plate is configured between the cylindrical body 72b engaged with the cylindrical rotor 72 and a cylindrical rotor 71 splined to the clutch shaft 70. Yes.

  A cylindrical rotating body 74 is loosely fitted on the outer periphery of the cylindrical rotating body 72, and a gear 74a that is always engaged with the third gear 40c of the center gear 40 is attached to the cylindrical rotating body 74. I have. Further, a turning clutch 82 composed of a multi-plate friction plate is formed between the cylindrical rotating body 74 and the cylindrical rotating body 71. A compression spring 75 is disposed between the rectilinear clutch 81 and the turning clutch 82, and the urging force of the compression spring 75 is set so that the rectilinear clutch 81 is “on”.

  A cylindrical body 76 having disk-like plates 76a and 76b for partitioning the linearly moving clutch 81, the compression spring 75, and the turning clutch 82, respectively, is integrally provided on the outer periphery of the cylindrical rotating body 71.

  When no pressure oil is introduced from the oil port 77, the compression spring 75 urges the cylinder rotation body 71 and the cylinder rotation body 72 to always engage with the “in” direction in which the straight-traveling clutch 81 is engaged. Yes. The rectilinear clutch 81 is always kept in the “on” state, and the turning clutch 82 is always kept in the “off” state.

  When pressure oil is introduced from the oil port 77, the piston 73 and the disk-like plates 76a and 76b of the cylindrical body 76 overcome the urging force of the spring 75 and shift to the left side in FIG. “OFF” state) and the turning clutch 82 is engaged (“ON” state).

  When the straight traveling clutch 81 is “ON”, the driving force from the auxiliary transmission 24 passes through the outer peripheral gear 40 a of the center gear 40 of the side clutch shaft 41 and the gear 72 a of the cylindrical rotating body 72, and the cylindrical rotating body 72. The cylindrical body 72b, the cylindrical body 76, the cylindrical rotating body 71, the linear clutch 81 and the clutch shaft 70 are rotated, and the transmission gear 78 integral with the clutch shaft 70 is always engaged with the transmission gear 78. The ring gear 53 of the differential gear mechanism 6 is rotated. At this time, since the turning clutch 82 is “disengaged”, the rotational power of the gear 74a of the cylindrical rotating body 74 that is always meshed with the third gear 40c of the center gear 40 is not transmitted to the clutch shaft 70 but is rotated in the cylindrical shape. The body 74 is idle.

  When the turning clutch 82 is “ON”, the straight-traveling clutch 81 is “OFF”, and the cylindrical rotating body 72 loosely fitted to the clutch shaft 70 is idled. The driving force from the three gears 40c rotates the cylindrical rotating body 71 from the cylindrical rotating body 74 through the turning clutch 82 and the cylindrical body 76 via the gear 74a of the cylindrical rotating body 74, and the rotating body. The clutch shaft 70 is driven by the rotation of 71. As a result, the transmission gear 78 fixed to the clutch shaft 70 rotates, and the ring gear 53 of the differential gear device 6 that is always engaged with the transmission gear 78 is rotated.

  The differential gear device 6 is provided with a ring gear 53 integrated with a differential case 54 provided on the outer periphery of the intermediate bevel gear 52, and side bevel gears 51L and 51R are rotatably supported on the support shaft 50. The left and right side gears 55L and 55R are fixed to the outside of the side bevel gears 51L and 51R, respectively.

  The side gear 55L always meshes with the transmission gear 64L, the side gear 55R constantly meshes with the transmission gear 64R, the transmission gear 64L and the gear 63aL are integral, and the transmission gear 64R and the gear 63aR are integral.

  As can be seen from FIG. 2, since the straight clutch 81 and the turning clutch 82 are provided on the clutch shaft 70 which is the same shaft, both the clutches 81 and 82 can be operated alternatively. become. Further, since the switching timing of both clutches 81 and 82 can be mechanically adjusted, complicated control is not required.

In the gear mechanism of the traveling mission device 14 configured as described above, the left and right side clutches 44L and 44R of the side clutch device 25 remain engaged when the combine is traveling straight, and the engine power is transmitted to the mission counter shaft of the auxiliary transmission 24. 33 is transmitted to, it is transmitted to the center gear 40 through the output gear 37 of the transmission counter shaft 33. Since the side clutch shaft 41 is engaged with the center gear 40, the rotational force of the center gear 40 is transmitted to the clutch gears 43L and 43R via the clutches 44L and 44R, and is always transmitted to the clutch gears 43L and 43R. The transmission gears 64L and 64R are engaged, and the left and right traveling crawlers 3 are rotated from the transmission gears 64L and 64R through the gears 63aL and 63aR of the reduction shaft 63 and the wheel gears 48L and 48R, respectively.

  By operating the auxiliary transmission lever 22, the auxiliary transmission shifter stay 32 corresponds to the gears 28, 29, 30 of the transmission input shaft 27 of the auxiliary transmission 24 and the gear 34, 35, 36 of the gear of the mission counter shaft 33, respectively. By engaging each other, it is possible to travel straight at an appropriate speed stage.

At this time, the rectilinear clutch 81 is “on” and the turning clutch 82 is “disengaged”, and the state of the differential gear device 6 during rectilinear advance is as follows.
(A) The driving force of the transmission counter shaft 33 is transmitted via the side clutches 44L and 44R of the side clutch device 25 and the clutch gears 43L and 43R of the side clutch shaft 41 via the pawl gears 40bL and 40bR of the center gear 40. Since the gears 64L and 64R are both rotating, the side gears 55L and 55R of the differential gear device 6 with which the transmission gears 64L and 64R are engaged respectively rotate at the same speed in the same direction. Accordingly, the differential case 54 and the ring gear 53 integrated with the differential case 54 rotate in the same direction via the side bevel gears 51L and 51R that rotate integrally with the side gears 55L and 55R, respectively, and mesh with the side bevel gears 51L and 51R. The intermediate bevel gears 52 and 52 a rotate around the support shaft 50.

  (B) The driving force of the mission counter shaft 33 is transmitted from the outer peripheral gear 40a of the center gear 40 to the rotating cylindrical body 72, and the cylindrical body 72b engaging with the rotating cylindrical body 72, the linear clutch 81, and the plate 76a of the cylindrical body 76 The power is sequentially transmitted to the cylindrical rotating body 71, the clutch shaft 70, the transmission gear 78, and the ring gear 53, and the bevel gear 52 also rotates in the same rotational direction as the ring gear 53.

  Since the ring gear 53 is thus rotated from the two systems (A) and (B), the gear ratios from the two systems (A) and (B) to the ring gear 53 are set to be the same. Accordingly, when the side clutch 44L or 44R is turned off, the power from the transmission system (b) is transmitted from the ring gear 53 to the side gears 55L and 55R, the transmission gears 64L and 64R, the counter gears 63aL and 63aR, and the wheel shaft gear 48L. , 48R, the shock is prevented. The turning power transmitted from the third gear 40 c integrated with the center gear 40 to the gear 74 a and the cylindrical rotating body 74 is rotated by the turning clutch 82.

Next, the operation of the gear mechanism when turning left will be described.
By tilting the steering lever 21 to the left, the shifter 47L is operated and the side clutch 44L is turned off, pressure oil is introduced from the oil port 77 by a mechanism (not shown), and the piston 73 and the cylindrical body 76 are shown in FIG. Move to the left of 2. By this movement, the straight traveling clutch 81 is set to “disengaged” and the turning clutch 82 is set to “on”. The rotational force of the center gear 40 and the third gear 40c integrally formed by welding corresponds to the corresponding gear 74a provided on the outer periphery of the cylindrical rotating body 74 of the turning clutch 82, the turning clutch 82, the cylindrical body 76, and the cylinder. Via the rotary member 71, clutch shaft 70, transmission gear 78, ring gear 53, side bevel gear 51L, side gear 55L, transmission gear 64L of the reduction shaft 63, gear 63aL, wheel shaft gear 48L, and crawler drive sprocket 16L. The left traveling crawler 3 is driven. At this time, the power of the center gear 40 drives the right traveling crawler 3 on the outer side of the turn from the clutch gear 43R via the transmission gear 64R, the gear 63aR, the wheel gear 48R, and the crawler driving sprocket 16R of the reduction shaft 63, respectively.

  The turning clutch 82 can control the multi-plate friction plate to a turning mode in which the oil pressure is set steplessly (continuously). The hydraulic pressure of the friction plate of the turning clutch 82 can be controlled by controlling the tilt angle detected by a potentiometer (not shown) attached to the steering lever 21 provided in the cockpit 20.

  Due to the relationship between the gear ratio of the third gear 40c of the center gear 40 and the gear 74a of the cylindrical rotating body 74, for example, when the turning clutch 82 is completely connected, the rotational speed of the side gear 55L is the side gear on the side clutch 44R side. Since it is set to be -1/3 of the rotational speed of 55R and a sudden turn (spin turn) state is established, it is possible to shift from a gentle turn to a brake turn and a sudden turn.

  That is, as shown in FIG. 2, when turning left, the side clutch 44R outside the turn is in the “on” state, so that the rotation of the wheel shaft gear 48R is transmitted from the clutch gear 43R at a constant rotation, and the clutch gear 43R The rotation transmits the side gear 55R at a constant rotation. On the other hand, when the rotational speed of the ring gear 53 is decelerated as the frictional force of the turning clutch 82 increases, the rotational speed of the side gear 55L decreases in proportion thereto. When the rotation speed of the ring gear 53 becomes 1/2 of the side gear 55R, the side gear 55L becomes zero rotation, the rotation speed from the side gear 55L via the wheel shaft gear 48L becomes zero, and the left traveling crawler 3 is braked. Although it is not, the so-called brake turning, in which the left traveling crawler 3 does not rotate, is performed.

  When the ring gear 53 further decelerates, the side gear 55L rotates in the reverse direction with respect to the rotation direction of the side gear 55R, and the left traveling crawler 3 rotates in the reverse direction, so that a so-called sharp turn is performed.

The reverse rotation speed of the side gear 55L with respect to the rotation speed of the side gear 55R is such that when the gear ratio of the gear 40c and the gear 74a is set to the point X in FIG. 3, the side gear 55L is −1/3 spin relative to the side gear 55R. It is possible to set up to the reverse rotation speed that can be executed until the turn.
Further, when the right turn is selected, the side transmission 44R is set to “OFF”, so that the traveling mission device 14 performs an operation completely opposite to the left turn.

  A gear transmission 19 having a relatively simple configuration is interposed between the auxiliary transmission 24 and the turning clutch 82 as described above, and the engagement pressure of the friction plate of the turning clutch 82 is adjusted, thereby reducing the speed. It is possible to switch to a state in which execution is possible from turning to braking turning and -1/3 sudden turning.

  Although the output shaft 65 to the cutting device is spline-engaged with the mission input shaft 27, conventionally, as shown in FIG. 6, the cutting output shaft 65, the output shaft 17 of the traveling HST 18, the wide transmission gear 26, The counter gear 61 and the transmission gear 62 of the HST counter shaft 60 are separated from the hydraulic tank formed by the case 12 of the traveling mission main body by wall surfaces and are provided independently. Therefore, conventionally, as shown in FIG. 6, oil is supplied to the cutting output shaft 65 through an oil passage 27a provided in the central shaft portion of the mission input shaft 27, and the spline engaging portion of the cutting output shaft 65 is driven by this oil. It was lubricated. Therefore, in order to produce the oil passage 27 a provided in the central shaft portion of the mission input shaft 27, it has become one factor for increasing the cost of the traveling mission device 14. Further, the oil seal 66 'is provided on the wall surface of the traveling mission case 12 where the cutting output shaft 65 is provided.

  Therefore, as shown in FIG. 5, an oil seal 66 is provided on the mission input shaft 27 side which is an input portion to the main body of the traveling mission device 14, and the output shaft 17, the wide transmission gear 26, and the counter gear 61 of the HST counter shaft 60. The hydraulic tank 67 provided with the transmission gear 62 is an oil tank completely independent from the main body case 12 of the traveling mission device. Thus, it is not necessary to prepare the oil passage 27a provided in the central shaft portion of the mission input shaft 27 as in the prior art, and the cutting output shaft 65 can be lubricated with the oil in the hydraulic tank 67. Therefore, the entire traveling mission device can be manufactured at a relatively low cost.

  The third gear 40c of the side clutch device 25 having a large diameter among the many gears in the traveling mission case 12 and the differential case gear (= ring gear) 53 of the differential gear device 6 are arranged in the width direction of the traveling mission device 14. Since the differential case gear (= ring gear) 53 is arranged on the opposite side of the third gear 40c with the virtual surface at the center of (the longitudinal direction of the wheel shaft 11) in the middle, the width direction of the traveling mission case 12 is narrowed. Can be compact.

  Further, the center of the traveling gear case 12 of the differential gear device 6 in the width direction and the center of the traveling mission case 12 of the transmission gear 64 for reduction are set at substantially the same position, so that the ring gear is placed inside the transmission gears 64L and 64R. Since there are 53, the width direction of traveling mission case 12 can be constituted narrowly, and it becomes compact.

  The turning control of the combine of this embodiment provided with the transmission equipped with the differential gear mechanism 6 in the control block diagram shown in FIG. 7 shows the braking pressure of the turning clutch 82 in the standard mode and the turning clutch 82 in the wet paddy mode. Braking pressure adjustment dials 68 and 69 for controlling the maximum braking pressure of each, a power steering position sensor 101 for detecting the tilt angle of the steering lever 21, the rotation detection sensors 102 and 103 for the left and right crawlers, and a turning mode In order to control the operating oil pressure of the side clutches 44L and 44R based on the detection switch 106, the turning force up switch 105, the detection value of the engine speed detection sensor 106, etc., the operating oil pressures of the left and right side clutch solenoids 108 and 109 and the turning clutch 82 are controlled. The proportional pressure solenoid 110 that adjusts the steering lever 21 according to the inclination angle of the steering lever 21 It is capable of providing an appropriate output.

  Switching between a standard turning mode (standard mode) during traveling on the field and road and a mode during swiveling (wet field mode) in the paddy field is performed by the changeover switch 104, and the steering control device 100 operates the steering lever during slow turning. When 21 is operated, the following control can be performed.

  Basically, as shown in FIG. 8 (a), the relationship between the inclination angle of the steering lever 21 and the braking pressure of the turning clutch 82 is provided with respective reference pressure values in the standard mode and the wet field mode, and the wet field is set more than the standard mode. The reference pressure value of the mode is configured to be low.

  Then, the braking pressure of the turning clutch 82 in the standard mode and the braking pressure of the turning clutch 82 in the wet paddy mode can be adjusted by the respective maximum braking pressure adjusting dials 68 and 69 as shown in FIG. Is set to an intermediate value between the installation ranges of the pressure adjustment dials 68 and 69.

Further, the relationship between the tilt angle of the steering lever 21 and the braking pressure of the turning clutch 82 can be changed and set as follows according to the turning traveling condition and the state in the field.
FIG. 9 shows the relationship between the tilt angle of the steering lever 21 and the braking pressure of the turning clutch 82. As shown in FIG. 9, when the steering lever 21 is most tilted, the braking pressure of the turning clutch 82 in the wet paddy mode and the braking pressure of the turning clutch 82 in the standard mode can be adjusted by the pressure adjusting dials 68 and 69, respectively. The lower limit value of the adjustment range of the braking pressure of the swing clutch 82 in the mode is the same as or substantially the same as the braking pressure of the reference value in the adjustment range of the swing clutch 82 in the wet paddy mode.

  As shown in FIG. 9, the lower limit value of the adjustment range of the turning pressure of the turning clutch 82 in the standard mode when the steering lever 21 is tilted to the maximum is the braking pressure of the reference value in the adjustment range of the turning clutch 82 in the wet paddy mode. By making them the same or substantially the same, the adjustment range of the braking force of the swing clutch 82 is widened in an appropriate range, and the operability and condition adaptability are improved.

  Setting of the braking pressure of the swing clutch 82 is performed using either the adjustment dial 68 or 69 shown in FIG. 8B. However, if the set braking pressure is too small, the turning radius becomes too large. Or it can adjust to an appropriate range by operating 69. However, if the adjustment range is too wide, fine adjustment with the adjustment dial 68 or 69 becomes difficult, and if the adjustment range is too narrow, the condition adaptability is lost.

  FIG. 10 shows the relationship between the tilt angle of the steering lever 21 and the braking pressure of the turning clutch 82, which is different from that in FIG. 9. In this case, the maximum operation of the steering lever 21 in the wet paddy mode ( The lower limit value of the braking pressure adjustment range of the turning clutch 82 at the maximum tilt angle is the same as or substantially the same as the pressure at which the straight-traveling clutch 81 is disengaged.

  With the above configuration, in the wet paddy mode, the swing clutch 82 is started up (10 kg) with a pressure (for example, 10 kg) that cuts the straight traveling clutch 81, so that it can turn only with a weak pressure. Ensure tropism. At this time, the upper limit value of the adjustment range of the braking pressure of the swing clutch 82 in the wet paddy mode is set to be the same as or substantially the same as the reference value in the adjustment range of the braking pressure of the swing clutch 82 in the standard mode.

  Thus, when the steering lever 21 is tilted to the maximum, the lower limit value of the braking pressure adjustment range in the wet paddy mode is set to the same or substantially the same pressure as the straight clutch 81 is disengaged, and the upper limit value of the braking pressure adjustment range is standard. By making the pressure the same or substantially the same as the reference value of the braking pressure of the swing clutch 82 in the mode, the adjustment range of the braking force is widened in an appropriate range, and the steering operability and condition adaptability are improved.

  Further, a turning force up switch 105 is provided. When the turning force up switch 105 is turned on, as shown in FIG. 11, the braking pressure of the turning clutch 82 is set so that the turning force is increased in both the standard mode and the wet paddy mode. It can also be set as the structure which can raise. At this time, each of the manual adjustment dials 68 and 69 in the standard mode and the wet paddy mode can be adjusted to the turning pressure as shown in FIG. 11 when the steering lever 21 is tilted to the maximum.

  If the pressure when the turning force up switch 105 is operated is fixed, when the braking pressure of the turning clutch 82 is set to be high, the fluctuation of the turning pressure is small and it is difficult to obtain the feel of the turning force up switch 105. There is. Conversely, if the turning pressure is set to a low value, the pressure fluctuation is large, and the shock to the airframe may be increased. Therefore, as described above, in addition to the braking pressure of the swing clutch 82 set by the manual adjustment dials 68 and 69 in both the standard mode and the wet field mode, it is possible to further increase the + alpha swing pressure. As a result, the above-described problems are solved, and the feeling of increasing the turning force is improved.

  When the braking pressure of the turning clutch 82 is set to be low, the running performance is improved in a wet field, but the braking pressure is insufficient when driving on the road, and turning may not be possible. In addition, when the braking pressure is set high, the crawler 3 is easily locked in a wet field and there is a problem that traveling performance is deteriorated. Therefore, in order to satisfy the field work and the road running, it is necessary to switch to the standard mode or adjust the braking pressure of the turning clutch 82 in the wet paddy mode every time the field work and the road running.

  In order to eliminate the above-described problems, the control content of the braking pressure of the swing clutch 82 may be different between the state where the threshing clutch (not shown) is turned on and the state where it is turned off when the wet paddy mode is selected.

  Specifically, as shown in the relationship diagram between the tilt angle of the steering lever 21 and the braking pressure of the turning clutch 82 in FIG. 12 and the flowchart in FIG. 13, the threshing clutch is selected based on on / off of the threshing clutch. When turning on, the braking pressure can be adjusted by the braking pressure adjustment dial 69 in the wet field mode. When the threshing clutch is disengaged, the braking pressure set in advance by the pressure adjusting diamond 69 is not used. It is almost the same pressure as the standard brake pressure).

  When the threshing clutch is disengaged, the same or substantially the same braking pressure as the reference braking pressure in the standard mode is set. This is to make it possible to cope with traveling on the road forgetting that the wetland mode is being selected.

  Thus, when the wetland mode is selected, the braking pressure of the turning clutch 82 can be set when the threshing clutch is turned on and off, respectively, the above problems are eliminated, the operability of the combine is improved, and the standard when traveling on the road Even if forget to switch to the mode or forget to adjust the braking pressure of the swivel clutch 82 in the wet paddy mode, the turning performance can be secured and the safety is improved. Also, the brake feeling when traveling on the road is almost the same as the standard mode.

  In addition, since the brake pressure can be adjusted in the field work in the wet paddy mode, the field adaptability and the traveling performance are improved.

  The present invention can be provided for a traveling mission device of a traveling vehicle such as a combine.

It is a left view of the combine of embodiment of this invention. It is a figure which shows a part of expanded sectional view of the traveling transmission apparatus of the combine of FIG. It is a related figure of the rotation speed of the gear of the differential gear apparatus of the traveling mission apparatus of FIG. FIG. 3 is an enlarged view of a clutch shaft portion of the traveling transmission device of FIG. 2. FIG. 3 is a partial cross-sectional view of the traveling transmission device of FIG. 2. It is a partial cross section figure of the conventional traveling transmission apparatus. It is a control block diagram for steering control of the combine of FIG. FIG. 8 is a diagram (FIG. 8A) showing a relationship between the turning clutch pressure when the steering lever of the embodiment of FIG. 1 is tilted and a plan view of the turning clutch braking pressure adjustment dial (FIG. 8B). is there. It is a figure which shows the relationship with the turning clutch pressure at the time of tilting of the steering lever of one Example of the combine of FIG. It is a figure which shows the relationship with the turning clutch pressure at the time of tilting of the steering lever of one Example of the combine of FIG. It is a figure which shows the relationship with the turning clutch pressure at the time of tilting of the steering lever of one Example of the combine of FIG. It is a figure which shows the relationship with the turning clutch pressure at the time of tilting of the steering lever of one Example of the combine of FIG. 13 is a flowchart for adjusting a turning clutch pressure when the steering lever of FIG. 12 is tilted.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Combine 2 Body frame 3 Traveling device (traveling crawler) 4 Traveling device main body 6 Differential gear mechanism 7 Mowing device support frame 8 Weeding shear 9 Mowing device 10 Threshing device 11L, 11R Wheel shaft 12 Traveling transmission case 13 Glen tank 14 Traveling Mission device 15 Auger 16L, 16R Crawler drive sprocket 17 Output shaft 18 Traveling HST
DESCRIPTION OF SYMBOLS 19 Gear transmission 20 Steering seat 21 Steering lever 22 Sub transmission lever 23 Main transmission lever 24 Sub transmission 25 Side clutch device 26 Wide transmission gear 27 Mission input shaft 27a Oil path 28 Large gear 29 Medium gear 30 Small gear 32 Sub transmission Shifter stay 33 Mission counter shaft 34 Large gear 35 Shifting gear 36 Small gear 37 Transmission gear 40 Center gear 40a Outer gear 40b Claw gear 40c Third gear 41 Side clutch shaft 42L, 42R Sleeve 43L, 43R Clutch gear 44L, 44R Side clutch 45L, 45R Bearing spacer 47L, 47R Shifter 48L, 48R Wheel shaft gear 46L, 46R Spring 50 Differential gear mechanism support shaft 51L, 51R Side bevel gear 52, 52a Intermediate bevel gear 53 Lin Gear 54 Differential case 55L, 55R Side gear 60 HST counter shaft 61 Counter gear 62 Transmission gear 63 Deceleration shaft 63aL, 63aR Counter gear 64L, 64R Transmission gear 65 Cutting output shaft 66, 66 'Oil seal 67 Hydraulic tank 68, 69 Pressure adjustment dial 70 Clutch shafts 71, 72, 74 Cylindrical rotating body 72 a Cylindrical rotating body gear 72 b Cylindrical body 73 Piston 74 a Gear 75 Compression spring 76 Cylindrical bodies 76 a, 76 b Plate 78 Transmission gear 77 Oil port 81 Straight-forward clutch 82 Rotating clutch 100 Steering Control device 101 Power steering position sensors 102, 103 Left and right crawler rotation speed detection sensor 104 Brake rotation mode changeover switch 105 Turning force up switch 106 Engine rotation speed detection sensors 108, 109 Id clutch solenoid 110 proportional pressure solenoid

Claims (1)

An engine provided on the vehicle body (2) ;
The motive power obtained by shifting the driving force from the engine is transmitted, and a traveling drive body ( 3 ) capable of turning which is provided on the left and right in the traveling direction;
A steering operation tool ( 21 ) for adjusting the steering operation of the traveling drive body ( 3 ) ;
The driving force transmitted from the engine to the traveling drive body (3) is shifted, and the hydraulic continuously variable transmission (18), the auxiliary transmission (24) for the main transmission and the steering operation tool ( 21 ) are steered. left and right track drive body during straight of the travel drive member rotational speed and to adjust the brake pressure turning clutch changing the turning performance (82) of the travel drive of the turning inner side in accordance with the operation amount (3) (3) ( 3, 3 ) a straight traveling clutch ( 81 ) for driving at a constant speed ,
A reaping device (9) provided on the front side of the traveling drive body (3);
In a combine equipped with a threshing device (10) for threshing cereals harvested by the reaping device (9) ,
Any of the traveling drive of the turning inner side during turning (3) and zero or standard mode almost to zero rotation Shitsuden mode the rotational speed increase than the set value of the standard mode of the turning inner traveling drive body during turning (3) A mode switch ( 104 ) that can set the travel mode,
With changing the brake pressure of the turning clutch (82) of said standard mode and Shitsuden mode respectively, adjustable adjusting the braking pressure of Shitsuden mode turning the clutch when threshing clutch of input of the threshing unit (10) (82) Means ( 68, 69 ) ;
When the steering operation tool ( 21 ) is operated with the maximum steering operation amount, the lower limit value of the adjustment range of the braking pressure of the swing clutch ( 82 ) in the standard mode is set to the braking of the swing clutch ( 82 ) in the wet paddy mode. The swivel clutch in the wet paddy mode when the steering operation tool (21) is operated with the maximum steering operation amount while being the same as or substantially the same as the reference value between the upper limit value and the lower limit value of the pressure adjustment range ( A control device ( 100 ) that makes the lower limit value of the adjustment range of the braking pressure of 82) the same as or substantially the same as the pressure at which the linear clutch (81) is disengaged ,
The traveling mission device (14) is transmitted from the engine with a hydraulic power continuously variable transmission (18) and a sub-transmission (24) for the main transmission and hydraulically transmitted from the engine. From the output shaft (17) from which the power shifted by the variable continuously variable transmission (18) is output, the wide transmission gear (26) provided on the output shaft (17), and the wide transmission gear (26) The counter gear (61) of the counter shaft (60) to which the motive power is transmitted is engaged with the cutting output shaft (65) to the reaping device (9) at the end, and the auxiliary transmission (24) is powered. Provided between the input shaft (27) to be input, the auxiliary transmission (24) of the input shaft (27) and the cutting output shaft (65), and the power from the counter gear (61) is transmitted. Transmission gear (62),
An oil seal (66) is provided on an input shaft (27) between the auxiliary transmission (24) and the transmission gear (62), and the hydraulic continuously variable transmission (18) is provided by the oil seal (66). A hydraulic tank (67) having an output shaft (17), the wide transmission gear (26), the counter gear (61), and the transmission gear (62) is provided independently of the main body case (12). Combine that is characterized by that.

Images