JP2009179213A - Working vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To safely adjust a wheel tread width of a working vehicle. <P>SOLUTION: In this working vehicle, a controller 14 is provided with a storage means for storing a tread set width during previous work also when the turning off an engine when a tread adjusting on/off-switch SW2 is automatically turned on during the previous work, a tread adjusting on/off-switch automatically maintaining a means for maintaining the automatic on-state of the tread adjusting on/off-switch SW2 when the tread set width when supplying power this time is the same as that during the previous work, and a tread adjusting on/off-switch automatically releasing means for releasing the automatic on-state of the tread adjusting on/off-switch SW2 when the tread set width of this time is different from that during a previous time. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a work vehicle such as an agricultural tractor.

A hydraulic cylinder that changes the tread of the front or rear wheel of the work vehicle, and a stroke sensor that detects this tread, and the tread of the front or rear wheel is changed from the standard state when the engine of the work vehicle is started When the stroke sensor detects the work vehicle, the left and right rear wheel brakes are operated until the on / off switch for changing the tread is operated from “on” to “off” and from “off” to “on”. It is known that it is configured to temporarily check the start of (Patent Document 1).
JP 2000-301906 A

  In the wheel tread width adjusting device for a work vehicle, the present invention is intended to ensure safety by preventing an inadvertent change of the tread width when the work is resumed while simplifying the operation.

  The invention according to claim 1 detects the tread width of the left and right wheels (6, 6) and the left and right wheels (6, 6) and the right and left tread hydraulic cylinders (34L, 34R) that adjust the expansion and contraction to change the width of the tread. Left and right tread stroke sensors (SE3, SE4), tread width adjustment dial (SW1) for setting the tread width of the left and right wheels (6, 6), and the tread width set by the tread width adjustment dial (SW1). In a work vehicle including a controller (14) having a tread control means for adjusting expansion and contraction of the left and right tread hydraulic cylinders (34L, 34R) and a tread adjustment on / off switch (SW2) for turning on / off the operation of the tread control means. When the tread adjustment on / off switch (SW2) is automatically turned on at the previous work, the tread setting at the previous work is set. Storage means for storing the width even when the engine is turned off. When the tread setting width at the time of power-on this time is the same as that at the time of the previous work, the tread adjustment which maintains the automatic on state of the tread adjustment on / off switch (SW2) On / off switch automatic maintaining means, and if the current tread setting width is different from the previous time, the tread adjustment on / off switch automatic release means for releasing the automatic on state of the tread adjustment on / off switch (SW2) is provided on the controller. (14) is provided with a work vehicle.

  According to the above configuration, the setting information of various switches and sensor detection information are read at the time of resuming work, and the tread adjustment on / off switch (SW2) at the previous work is automatically turned on, the tread setting at the current work is set. If the width is the same as in the previous work, the work is resumed while the tread adjustment on / off switch (SW2) is maintained in the automatic on state. If the current tread setting width is different from the previous tread setting width, the tread adjustment on / off switch (SW2) is changed from automatic on to off, and the operation is resumed.

  The invention according to claim 2 detects the tread width of the left and right wheels (6, 6) and the left and right wheels (6, 6) and the left and right wheels (6, 6), and the left and right wheels (6, 6). Left and right tread stroke sensors (SE3, SE4), tread width adjustment dial (SW1) for setting the tread width of the left and right wheels (6, 6), and the tread width set by the tread width adjustment dial (SW1). In a work vehicle including a controller (14) having a tread control means for adjusting expansion and contraction of the left and right tread hydraulic cylinders (34L, 34R) and a tread adjustment on / off switch (SW2) for turning on / off the operation of the tread control means. When the tread adjustment on / off switch (SW2) is automatically turned on at the previous work, the tread setting at the previous work is set. Storage means for storing the width even when the engine is turned off. When the tread setting width at the time of power-on this time is the same as that at the time of the previous work, the tread adjustment which maintains the automatic on state of the tread adjustment on / off switch (SW2) When the on / off switch automatic maintaining means and the tread adjustment on / off switch (SW2) are automatically turned on at the previous work, the tread is set until the tread width adjustment dial (SW1) is made equal to the tread setting width at the previous work. The work vehicle is characterized in that the controller (14) includes tread width adjustment dial setting invalidating means for invalidating the width setting.

  According to the above configuration, the setting information of various switches and sensor detection information are read at the time of resuming work, and the tread adjustment on / off switch (SW2) at the previous work is automatically turned on, the tread setting at the current work is set. If the width is the same as in the previous work, the work is resumed while the tread adjustment on / off switch (SW2) is maintained in the automatic on state.

  When the tread setting width of this time is different from the previous time and the tread adjustment on / off switch (SW2) is automatically turned on at the previous work, the tread width adjustment dial (SW1) is set to be the same as the tread setting width at the previous work. When the tread width adjustment dial (SW1) is operated in the same manner as the tread setting width at the previous work, the work is resumed.

  According to the first aspect of the present invention, if the tread setting width of the left and right wheels (6, 6) is the same at the time of resuming work, the tread adjustment on / off switch (SW2) is automatically turned on while simplifying the operation. Since the automatic tread adjustment is turned off when the tread setting width is changed, the tread width can be safely changed without being inadvertently changed.

  In the invention of claim 2, the tread adjustment on / off switch (SW2) is prevented from forgetting to turn on automatically, and the tread adjustment on / off is set when the tread setting width of the left and right wheels (6, 6) is the same when the work is resumed. Work can be resumed quickly with the switch (SW2) turned on automatically, and when the operator inadvertently operates the tread width adjustment dial (SW1) while the work is stopped, Work can be resumed at the tread width and it is safe.

Hereinafter, an agricultural tractor including an embodiment of the present invention will be described. FIG. 1 is a side view of the tractor, and FIG. 2 is a rear view of the tractor.
As shown in FIG. 1, the tractor 1 is provided with an engine E in a bonnet 2 on the front side of the vehicle body, and a clutch housing inside the main clutch and a transmission case 3 inside the gear type transmission are integrally connected to the rear part of the engine E. Provided. The left and right rear axle cases 4 and 4 that can be treaded are provided on both the left and right sides of the mission case 3, and the rear wheels 6 and 6 are provided on the left and right sides of the cases 4 and 4. Further, a front axle case is provided below the engine E so as to be able to roll around an axial center in the front-rear direction, and front wheels 5 and 5 are provided on both left and right sides.

  Next, the periphery of the cockpit 7 of the tractor 1 will be described. As shown in FIGS. 1 and 3, an operation panel 13 having an alarm buzzer 11 and a liquid crystal monitor 12 serving as a notification unit is provided behind the bonnet 2, and the steering handle 8 protrudes behind the operation panel 13. The left and right front wheels 5 and 5 are steered.

  A shift lever 9 for switching the transmission, a work implement elevating lever 10 and the like project from the side of the cockpit 7, and a work implement elevating lever sensor for detecting an operation position is provided at the rotating base of the work implement elevating lever 10. SE1 is provided, and a shift lever sensor SE6 for detecting the operation position of the shift lever 9 is provided. Further, a tread width adjustment dial SW1 and a tread adjustment on / off switch SW2, which will be described later, are provided near the guides of these levers, and these setting signals are transmitted to the controller 14 below the cockpit 7. .

  A cylinder case 22 having a lifting cylinder (not shown) for raising and lowering the work implement is provided at the upper part of the mission case 3. The lift arm 23 supported by the cylinder case 22 is rotated in the vertical direction by extending and contracting the piston of the lift cylinder (not shown), and the work machine 24 connected thereto is lifted and lowered.

  One of the lift arms 23 is provided with a lift arm angle sensor SE2 that detects the height of the work implement. The detection position of the work implement lift lever sensor SE1 of the work implement lift lever 10 and the rotation of the lift arm 23 are provided. The controller 14 is configured so that the switching control valve for raising or lowering the work implement in the hydraulic circuit is switched by the controller 14 so as to coincide with the dynamic setting position. In the illustrated example, a rotary work machine 24 is connected as a work machine.

Next, the transmission configuration from the transmission case 3 to the rear wheels 6 and 6 will be described with reference to FIG.
A rear wheel differential mechanism 31 is provided in the center of the rear side of the transmission case 3, and left and right rear axle cases 4 and 4 are attached to the left and right sides of the transmission case 3. Power is transmitted to the mechanism 31. Brake disks 36 and 36 are mounted on the left and right output shafts 31L and 31R of the rear wheel differential mechanism 31, and are operated independently by the left and right brake cylinders.

  The inner transmission cylinders 4a and 4a are pivotally mounted on the left and right inner portions of the left and right rear axle cases 4 and 4 so that they can only rotate and cannot move in the left and right directions, and the left and right axle support cylinders 4b and 4b are disposed on the left and right outer parts. Is supported so as to be rotatable and movable in the left-right direction.

  The left and right ends of the left and right output shafts 31L and 31R and the inner ends of the inner transmission cylinders 4a and 4a are connected to the planetary gear unit 37 (the sun gear 37a provided on the left and right output shafts 31L and 31R, the inner transmission cylinder 4a. , 4a and a ring gear 37c fixed to the inside of the left and right wheel support case 4). The rear wheel shafts 6a and 6a are mounted on the left and right axle support cylinders 4b and 4b, and the left and right inner transmission cylinders 4a and 4a and the rear wheel shafts 6a and 6a are spline-fitted to form a tread. It is configured so that power can be transmitted while adjusting.

  Further, tread hydraulic cylinders 34L and 34R for adjusting the tread are provided on the front side portions of the left and right rear axle cases 4 and 4, and are connected to the front ends of the cylinders 34L and 34R and the left and right axle support cylinders 4b and 4b. The left and right stroke sensors SE3 and SE3 that are pushed and pulled together with the expansion and contraction of the pistons of the cylinders 34L and 34R are arranged side by side.

  Although not shown in the drawings, a tread can be fixed by manual operation by providing a lock hole penetrating the left and right rear axle cases 4 and 4 and the left and right axle support cylinders 4b and 4b and inserting a pin therethrough. It is configured.

Next, the hydraulic circuit configuration of the tractor 1 will be described with reference to FIG.
The hydraulic pressure discharged from the hydraulic pump 41 is sent to the horizontal cylinder 44 that adjusts the rolling of the vehicle body of the tractor 1 via the external extraction valve 42a, the diversion valve 42b, and the rolling control valve 43. Further, the hydraulic pressure is sent to the return-type left and right tread hydraulic cylinders 34L and 34R via the flow dividing valve 42b, the rolling control valve 43, the flow dividing valve 42c, and the left and right tread control valves 43L and 43R.

Next, a control block configuration will be described with reference to FIG.
The controller 14 includes a CPU that processes various signals, an EEPROM that stores various control programs, a RAM that detects signals and setting values, a timer, and the like. The input section includes a tread width adjustment dial SW1, a tread adjustment on / off switch SW2, a tread adjustment switch (left) SW3, a tread adjustment switch (right) SW4, a tread adjustment switch (extension) SW5, and a tread adjustment switch (shrink). SW6, check mode switch SW7, work implement lifting lever sensor SE1, lift arm angle sensor SE2, tread stroke sensor (left) SE3, tread stroke sensor (right) SE4, vehicle speed sensor SE5, shift lever sensor SE6 are connected. Yes.

  Further, the tread control valve 43L, 43R for operating the tread left extending solenoid SL1, the tread left contracting solenoid SL2, the tread right extending solenoid SL3, the tread right contracting solenoid SL4, and the liquid crystal display unit 46 of the operation panel are connected to the output unit. is doing.

  7, the operation panel 13 of the tractor 1 includes a tread width adjustment dial SW1, a tread adjustment switch (left) SW3 for the left rear wheel 6, and a tread adjustment switch (right) for the right rear wheel 6. SW4, a tread adjustment switch (extension) SW5 for adjusting the expansion of the left and right wheels 6 and 6 at the same time, and a tread adjustment switch (contraction) SW6 for adjusting the contraction of the left and right wheels 6 and 6 at the same time are provided.

  The liquid crystal display unit 46 of the operation panel 13 is provided with a scaled left display unit 46a for displaying tread adjustment of the left wheel 6 and a scaled right display unit 46b for displaying the tread of the right wheel 6. The tread adjustment state of the rear wheels 6 and 6 is displayed.

Next, rear wheel tread adjustment control of the controller 14 will be described.
In this embodiment, the tread width adjusting dial SW1 for setting the tread width of the left and right rear wheels 6 and 6 is adjusted in the tractor capable of adjusting the tread of the left and right rear wheels 6 and 6 by expanding and contracting the left and right tread hydraulic cylinders 34L and 34R. On / off switch SW2, tread stroke sensor (left) SE3 and tread stroke sensor (right) SE4 for detecting the tread adjustment amount of the left and right rear wheels 6, 6 are provided. 6 and 6 are adjusted.

  The tread adjustment on / off switch SW2 is configured as a rebound switch without a switch lock mechanism so that it can be set (holding on) or reset (holding off) each time the switch is pressed. Only when the tread adjustment on / off switch SW2 is in the on state, the operation position of the tread width adjustment dial SW1 and the detection positions of the tread stroke sensor (left) SE3 and the tread stroke sensor (right) SE4 substantially coincide with each other. The left and right tread hydraulic cylinders 34L and 34R are feedback-controlled.

  The tread adjustment mechanism of the rear wheels 6 and 6 may be displaced from the adjustment position due to oil leakage or the like. In addition, if the rear wheels 6 and 6 are always feedback-controlled to the set adjustment position and are held at the tread adjustment position, the operator suddenly touches the adjustment dial and the tread adjustment mechanism moves to an unexpected position. A malfunction occurs.

  However, according to the above configuration, when the tread adjustment on / off switch SW2 is set to on, feedback control is always applied and the left and right rear wheels 6, 6 are held at the set zoom position. If the tread width adjustment dial SW1 is likely to be erroneously operated, the tread adjustment on / off switch SW2 is turned off to stop the feedback output, thereby preventing unnecessary movements of the left and right rear wheels 6 and 6 from being unpredictable. Can do.

Next, the total turning control of the controller 14 and the related adjustment control of the rear wheel tread will be described.
When the controller 14 performs full turn control, that is, when the steering handle 8 is turned by a certain angle or more, approximately double speed power is transmitted to the front wheels 5 and 5 via the speed increasing mechanism and the vehicle can turn slightly. Further, in this full turn control, the double speed transmission is stopped when the vehicle speed becomes, for example, 5 km / h or more for safety.

  Next, the control related to this all-turn control and the rear wheel tread width adjustment will be described. When the work is started by the tractor, the controller 14 reads detection values and setting values from various sensors and switches, and determines whether the tread adjustment on / off switch SW2 is turned on or not. It is determined whether or not to execute control.

  When the tread adjustment on / off switch SW2 is turned on, the operating angle of the entire turning control is set according to the set value of the tread width adjusting dial SW1, and when the adjustment width of the left and right rear wheels 6 and 6 is a narrow set value, the front wheel When the turning angle of 5 or 5 is small (for example, 28 degrees), full turn control for doubling the front wheels 6 and 6 is started, and when the left and right rear wheels 6 and 6 are wide set values, the front wheels 5 and 6 When the turning angle of 5 is large (for example, 40 degrees), full turn control for doubling the front wheels 6 and 6 is started.

  If the steering handle is turned more than a certain angle during the full turn of the tractor, in addition to the full turn control, the work implement automatic lift control that automatically raises the work implement, and the full turn control and the work implement automatic lift control are added. Thus, when performing automatic brake control or the like that automatically brakes the rear wheel 6 on one side at the time of full turn, the control may be similarly performed according to the adjustment width of the rear wheels 6 and 6. .

According to the said structure, regardless of the width of the tread of the left and right rear wheels 6, 6, the tractor can be properly fully turned and the work machine can resume work from the adjacent work position.
Next, another implementation of the tread width adjustment control will be described.

  In this embodiment, the tread width of the left and right rear wheels 6 and 6 is configured to be extendable and contractable by the left and right tread hydraulic cylinders 34L and 34R, and the tread width of the left and right rear wheels 6 and 6 is tread stroke sensor (left) SE3, tread stroke sensor. (Right) When the tread adjustment on / off switch SW2 is automatically turned on during the previous operation in the tractor that controls the expansion and contraction of the left and right tread hydraulic cylinders 34L and 34R so that it can be automatically adjusted to the desired tread width detected by SE4 The tread setting width at the time of the previous work is stored in the non-volatile memory which is not erased even when the power is turned off when the engine (E) is stopped, and the tread setting width at the time of power-on at the start of the engine (E) is stored. In the same case as in the previous work, the tread adjustment on / off switch SW2 is automatically turned on. Further, when the tread setting width is different from the previous work, the tread adjustment on / off switch SW2 is automatically turned off.

  Conventionally, the tread width adjustment dial SW1 can be changed regardless of the power on / off state. Even if the tread adjustment on / off switch SW2 is automatically turned on at the previous work, if the tread adjustment on / off switch SW2 is turned on automatically unconditionally when the power is turned on again, the tread setting width is not changed. If the tread width is changed, the tread width is changed against the operator's intention, which is dangerous, and there is a possibility that the crop is damaged by an unintended change of the tread width.

  In addition, if the tread width adjustment switch SW2 is automatically turned off unconditionally at the time of starting the engine, it is necessary to operate the tread adjustment on / off switch SW2 automatically every time the engine E is started. There is.

  However, according to the above configuration, when the tread adjustment on / off switch SW2 is automatically turned on, if the tread setting width of the tread width adjustment dial SW1 is the same as the previous work, the automatic on state is maintained. There is no need to operate automatically every time it is restarted, and the operation can be simplified.

  Further, when the tread width of the tread width adjustment dial SW1 is changed, “change tread width” is displayed on the liquid crystal monitor 12 and the tread adjustment on / off switch SW2 is automatically turned off. The width is safe without changing.

  Moreover, you may comprise as follows. The tread width of the left and right rear wheels 6, 6 is configured to be extendable by the left and right tread hydraulic cylinders 34L, 34R, and the tread width of the left and right rear wheels 6, 6 is determined by the tread stroke sensor (left) SE3 and the tread stroke sensor (right) SE4. If the tread adjustment on / off switch SW2 is automatically turned on during the previous operation in the tractor that controls the expansion and contraction of the left and right tread hydraulic cylinders 34L and 34R so that it can be automatically adjusted to the desired tread width, The tread setting width at the time is stored in a nonvolatile memory that is not erased even when the power is turned off. When the tread adjustment on / off switch SW2 is automatically turned on at the previous work and the tread setting width of the tread width adjustment dial SW1 is different from that at the previous work, the LCD monitor 12 displays “tread width is different”. The tread width adjustment dial setting invalidating means is provided to disable the tread width setting until the operator sets the same tread setting width at the previous work. The operation is resumed with the switch SW2 turned on automatically.

  According to the above configuration, when the tread adjustment on / off switch SW2 is automatically turned on at the previous work while preventing forgetting to automatically turn on the tread adjustment on / off switch SW2, the tread setting width is the same as that at the previous work. In this case, the resuming operation can be performed quickly while simplifying the operation. If the tread setting width is different from the previous work, the adjustment operation of the tread width adjustment dial SW1 is disabled until it matches the tread width, so that the treads of the left and right rear wheels 6 and 6 against the operator's will. The width does not change greatly and is safe.

Next, the change of the adjustment width of the tread width adjustment dial SW1 will be described.
As shown in FIG. 7, the tread width adjustment dial SW1 is configured so that the rear wheel tread width can be adjusted while increasing or decreasing by a predetermined width by selecting and setting from a narrow “1” to a wide “5”. . And about the tread width changed and set by this "1-5", you may comprise so that the adjustment amount for every unit scale can be set and changed widely.

  For example, when the tread adjustment on / off switch SW2 and the tread adjustment switch (left) SW3 on the operation panel 13 are pressed at the same time, the mode shifts to the tread width change mode, the tread width adjustment screen is displayed on the liquid crystal display unit 46, and the tread change width “ “Large, Medium, Small” is displayed. Next, every time the tread adjustment switch (elongation) SW5 is pressed, the selection setting of “large, medium, small” is changed. When the tread adjustment on / off switch SW2 and the tread adjustment switch (right) SW4 are simultaneously pressed, the tread change mode is selected. Ends.

  According to the above configuration, the operator can change the adjustment width of the tread width adjustment dial SW1 to be wide and narrow, and can adjust the tread of the rear wheel according to his / her preference and working condition.

  In addition, the tread adjustment switch (extension) SW5 is pressed and the buzzer sound increases in sequence as the rear wheel tread width becomes wider. Also, the tread adjustment switch (shrink) SW6 is pressed and operated to sequentially increase the rear wheel tread width. It may be configured such that the buzzer sound is gradually reduced as the width becomes narrower. If comprised in this way, the operator can know the rear-wheel tread width sensuously from a sound.

Next, the raising / lowering control apparatus of the working machine 24 is demonstrated based on FIG.1 and FIG.8.
As shown in FIG. 1, a work machine 24 is connected to the rear portion of the tractor 1 via an upper link 25 and left and right lower links 26, 26, and the work machine 24 can be moved up and down by a lift arm 23. A plurality of front connection holes 26a, standard connection holes 26b, and rear connection holes 26c are provided in the rear part of the left and right lower links 26, 26 in the front-rear direction. The connecting pin on the side is inserted so that the work machine 24 can be connected.

  Also, a work machine connection changeover switch (not shown) for switching and setting which of the connection holes 26a, 26b, and 26c is connected to the work machine 24 is provided, and the work machine 24 is connected to any of the connection holes 26a, 26b, and 26c. It is configured so that it can be set whether it is connected. Instead of this work implement connection changeover switch, it may be detected which of the connection holes 26a, 26b, 26c is connected by a work implement connection sensor (not shown).

  Further, when the steering handle 8 is turned by a predetermined angle or more during the entire turn at the shore of the tractor 1, the entire turn control is performed so that the front wheels 5 and 5 are turned while being rotated at an increased speed. The working machine 24 is configured to automatically raise the working machine 24 from a lower working position to a predetermined height, and to perform a working machine lifting control that lowers the working machine 24 to the working position when returning to linear traveling.

  And in this work implement raising / lowering control, as shown to FIG. 8 (B), raising / lowering speed correction | amendment control is made. When the detection information of the various sensors and the switch setting information are read into the controller 14 (step S1), the switching determination of the work implement connection changeover switch (not shown) is made (step S2). If the connection is to the standard connection hole 26b, the correction coefficient is “1” (step S3). If the connection is to the front connection hole 26a, the correction coefficient is “0.9” (step S4). If the connection is to the rear connection hole 26c, the correction coefficient is corrected to “1.1” (step S5). Therefore, the raising / lowering control of the working machine 24 is performed at the raising / lowering speed corrected by these correction coefficients.

According to the said structure, it can be raised to predetermined height with a predetermined timing also in the connection state of any working machine connection hole.
In the controller 14, the automatic control switch (not shown) is turned on in the automatic control state, the manual adjustment state of the cut, the parallel control state of the tractor 1 and the work implement 2, and the tilt control state of the tractor 1, The elevation speed correction is executed.

  The correction coefficient “1, 0.1, 1.1” may be corrected. When the work implement connection changeover switch (not shown) “1” is held down and the work implement connection changeover switch “2” is pressed for a predetermined time (for example, 3 seconds), the correction coefficient is changed from “1 to 0.9”. . When the work implement connection changeover switch “3” is pressed for a predetermined time while the work implement connection changeover switch “2” is being pressed, the correction coefficient is changed from “0.9 to 1.1”. Further, when only the work implement connection changeover switch “1” is kept pressed for a predetermined time, the standard value “1” is changed.

  When the entire turn is completed and the vehicle returns to straight running, the work implement 24 is automatically lowered and the tilling work is resumed. And if this work implement automatic raising / lowering control is operated incorrectly, there is a risk that the work implement (rotary tilling device) 24 will do the dashing and the tilling work cannot be performed, so the turning control on / off switch (not shown) is automatically turned on. In addition, it can be executed when the following conditions are satisfied.

  That is, (1) the brake device is in an inoperative state, (2) when the work unit 24 is lowered, the PTO clutch is engaged and is in a rotatable state, and (3) the auxiliary transmission (not shown) is at a low speed. It is a working speed, (4) the inner rear wheel brake is automatically applied during a full turn, and (5) when a predetermined time elapses after the work implement 24 is raised before the full turn control. It is configured to be executed when the condition that continuous work that does not automatically lower the work implement 24 even if the vehicle goes straight after turning is satisfied.

  According to the above-described configuration, it is possible to perform the tilling operation smoothly while preventing the dashing when the work machine (rotary tilling device) 24 is lowered during the full turn control while simplifying the operation of the operator.

Next, another control example will be described based on FIG.
In this embodiment, a pressure detection sensor (not shown) is provided to measure the connection pressure of each clutch of the tractor 1 so that it can be displayed on the liquid crystal monitor 12 of the meter panel 13. When a switch (not shown) is provided and a measured value is input from the clutch sensor, normal clutch pressure measurement display control is executed when the clutch pressure control automatic on / off switch is automatically turned on. Further, when the clutch pressure control automatic on / off switch is automatically turned on, the check mode of the pressure detection sensor is executed. With this configuration, the check mode of the pressure detection sensor can be easily executed, and the clutch pressure can be measured quickly.

  As shown in FIG. 9, when control is started, detection information of various sensors and switch setting information are read into the controller 14 (step S11), and it is determined whether or not a measured value of the clutch pressure is input. (Step S12). If Yes, it is determined whether or not the clutch pressure control automatic on / off switch has been operated “from on to off” (step S13). If Yes, the controller 14 sets a clutch pressure control automatic determination flag. (Step S14). Next, the connection state of the clutch pressure sensor is determined (step S15), and if it is Yes, the clutch pressure control mode is determined (step S16).

  Further, it is determined whether or not the clutch control automatic ON / OFF switch has been operated from OFF to ON (step S13). If NO, it is determined whether or not the determination flag for the clutch pressure control mode of the controller 14 is set. If it is No (step S17), the check mode of the clutch pressure sensor of the controller 14 is determined (step S18). When the clutch pressure display control or the check mode of the controller 14 is confirmed, the control is started in the confirmed mode (step S19).

  That is, when the clutch pressure display control mode is determined, the measurement information of the clutch pressure sensor is displayed on the liquid crystal monitor 12 of the meter panel 13. In the check mode of the clutch pressure sensor, the clutch pressure is detected by the clutch pressure sensor and displayed on the liquid crystal monitor 12 to determine whether the pressure is appropriate.

Next, control of the semi-crawler tractor will be described.
As shown in FIG. 10, a pair of left and right front wheels 5, 5 are provided on the front side of the semi-crawler type tractor, and a pair of left and right crawler travel devices 64, 64 are mounted on left and right rear axles 63, 63 provided on the rear of the body. A semi-crawler type agricultural tractor 1 is configured. Although not shown, a rotary tiller is connected to the rear side of the machine body via a three-point link mechanism. It is composed.

  The left and right crawler travel devices 64, 64 are a crawler frame 71 that is rotatably mounted around a cylinder for covering the left and right rear axle 63 in the rear axle case 65, a drive sprocket 72 that is driven by the rear axle 63, A front guide wheel 73 supported by the crawler frame 71 so as to be movable in the front-rear direction, a rear guide wheel 74 supported by the rear part of the crawler frame 71, and a lower part of the crawler frame 71 are supported along the front-rear direction. And a traveling crawler 76 wound around the drive sprocket 72, the front guide wheel 73, the rear guide wheel 74, and the intermediate wheel 75,.

  Further, as shown in FIG. 11, left and right crawler frames 71, 71 are supported swingably around the cylinders of the rear axle cases 65, 65, and are swingably supported. The attached left and right check chain mounting brackets 77 and 77 are extended so as to be positioned behind the left and right upper frame portions 71a and 71a. Left and right check chains (not shown) are attached to the left and right check chain mounting brackets 77 and 77 to prevent the left and right lower links 26 and 26 from shaking left and right.

  The left and right rear stoppers 78a and 78a attached to the rear sides of the left and right upper frame parts 71a and 71a and the left and right rear stoppers 78b and 78b attached to the left and right check chain mounting brackets 77 and 77 are brought into contact with each other. The left and right upper frame portions 71a and 71a are prevented from shaking to the rear side.

  Also, left and right front stoppers 79a and 79a are attached to the front side portions of the left and right upper frame portions 71a and 71a, and left and right front stoppers 79b and 79b are attached via left and right cabin mounting brackets 80 and 80 attached to the left and right rear axle cases 65 and 65, respectively. The stoppers 79a, 79a, 79b, 79b are brought into contact with each other to prevent the left and right upper frame portions 71a, 71a from shaking forward.

  According to the above configuration, the crawler frames 71 and 71 can be prevented from shaking back and forth using the existing chain brackets 77 and 77 and the cabin mounting brackets 80 and 80, thereby simplifying the configuration. Can do.

  Also, a semi-crawler tractor is provided with a controller (not shown), and detection information from various sensors (not shown) and ON / OFF information of various switches are input to the controller. When the steering handle 8 is turned by a predetermined angle or more during turning, the turning control for turning sharply while applying a brake to the rear axle 63 inside the turning is configured. Then, when the turning starts, the work machine automatically rises from the work position, and when returning to straight running, the work machine is controlled to be lifted and lowered to the work position.

  In addition, a drive pulse is output from the controller to the brake control valves for the left and right rear axles 63 and 63 via the brake drive means. As shown in FIG. 12, for example, a brake switch SW8 is provided on a lift lever 81 for lifting the work implement. When the brake switch SW8 is pressed, the rear axle brake inside the turn is braked, for example, "the brake is operated for 1 second and then rests for 0.5 second". When the brake switch SW8 is not pressed, the vehicle is configured to turn while the brake is continuously applied to the rear axle 63 inside the turn.

  According to the above configuration, by pushing the brake switch SW8 during full turn control, it is possible to turn gently while operating the rear axle brake inside the turn for a predetermined time and pausing for a predetermined time while facilitating the operation. Therefore, it is possible to turn while reducing the amount of dirt in the field and reducing the unevenness.

  Moreover, you may comprise as FIG. For example, left and right brake switches SW9 and SW10 are provided on a lift lever 81 for lifting the work implement. Connected to the input side of the controller 14 are left and right brake switches SW9 and SW10, left and right brake on / off switches SW11 and SW12 of the left and right brake switches SW9 and SW10, and a brake adjustment dial switch SW13. Driving means for the left and right brake control valves 82 and 82 are connected to the output of the controller 14. When the left and right brake switches SW9 and SW10 are pressed, for example, “the brake operates for 1 second and then stops for 0.5 seconds” is configured.

  According to the above configuration, when the left and right brake switches SW9 and SW10 are pressed, the brake is intermittently operated, and the left and right brakes can be gently turned while reducing the amount of crawling by the crawler.

Side view of agricultural tractor Rear view of agricultural tractor Front view of the operation panel Transmission case, rear wheel cut back view Hydraulic circuit diagram Control block diagram Front view of the operation panel (A) Side view of lower link (B) Flow chart flowchart Side view of a semi-crawler tractor Side view and rear view of the rear of the mission case Rear view of the control lever Operation lever and control block diagram

Explanation of symbols

1 Working vehicle 5 Wheel (front wheel)
6 wheels (rear wheels)
14 Controller 34L Left tread hydraulic cylinder 34R Right tread hydraulic cylinder SW1 Tread width adjustment dial SW2 Tread adjustment on / off switch SE3 Tread stroke sensor (left)
SE4 tread stroke sensor (right)

Claims (2)

  Left and right tread hydraulic cylinders (34L, 34R) that adjust to expand and contract to change the tread width of the left and right wheels (6, 6), and a left and right tread stroke sensor (SE3) that detects the tread width of the left and right wheels (6, 6) , SE4), the tread width adjusting dial (SW1) for setting the tread width of the left and right wheels (6, 6), and the tread width set by the tread width adjusting dial (SW1) to the left and right tread hydraulic cylinders (34L, 34R) In a work vehicle having a controller (14) having a tread control means for adjusting expansion and contraction and a tread adjustment on / off switch (SW2) for turning on and off the operation of the tread control means, the tread adjustment at the previous work is performed. When the on / off switch (SW2) is automatically turned on, the tread setting width at the previous work is turned off. If the tread setting width at the time of power-on this time is the same as that at the previous work, the tread adjustment on / off switch automatically maintains the tread adjustment on / off switch (SW2) automatically. The controller (14) has a tread adjustment on / off switch automatic release means for releasing the automatic on state of the tread adjustment on / off switch (SW2) when the maintaining means and the current tread setting width are different from the previous time. A work vehicle characterized by comprising.   Left and right tread hydraulic cylinders (34L, 34R) that adjust to expand and contract to change the tread width of the left and right wheels (6, 6), and a left and right tread stroke sensor (SE3) that detects the tread width of the left and right wheels (6, 6) , SE4), the tread width adjusting dial (SW1) for setting the tread width of the left and right wheels (6, 6), and the tread width set by the tread width adjusting dial (SW1) to the left and right tread hydraulic cylinders (34L, 34R) In a work vehicle having a controller (14) having a tread control means for adjusting expansion and contraction and a tread adjustment on / off switch (SW2) for turning on and off the operation of the tread control means, the tread adjustment at the previous work is performed. When the on / off switch (SW2) is automatically turned on, the tread setting width at the previous work is turned off. If the tread setting width at the time of power-on this time is the same as that at the previous work, the tread adjustment on / off switch automatically maintains the tread adjustment on / off switch (SW2) automatically. When the maintenance means and the tread adjustment on / off switch (SW2) are automatically turned on at the previous work, the tread width setting is disabled until the tread width adjustment dial (SW1) is made the same as the tread setting width at the previous work. The work vehicle, wherein the controller (14) is provided with a tread width adjustment dial setting invalidating means.

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