JP5955803B2 - Work vehicle - Google Patents

Description

  The present invention relates to a work vehicle technology capable of changing a tread.

  Conventionally, work vehicle technology capable of changing the tread has been publicly known. For example, as described in Patent Document 1.

  In the technique described in Patent Document 1, when the tread change switch is turned on, the tread of the tractor is changed so as to become a tread (set value) set in advance by the tread width setting device. This tread change is restricted to only take place when the tractor is running at low speed. By comprising in this way, the friction with the wheel at the time of changing a tread and the ground can be reduced, and the damage of the said wheel and another member can also be prevented by extension.

  However, the work vehicle configured as described above is disadvantageous in that the following situation may occur.

  In other words, if the key switch is turned off while the tractor tread is being changed to the set value, the tractor engine stops and the hydraulic and electrical equipment also stops, and the tread change is also stopped. The

  After that, when the key switch is turned on to start the tractor engine, the hydraulic equipment and the electric equipment are started, and when the tractor starts traveling at a low speed, the tread starts to be changed to the set value again.

  In this case, the operator who operates the tractor with the key switch turned on may be a different person from the operator who previously operated the key switch, or even the same person may change the tread. If the user forgets that the key switch is turned off, the tread change is unexpectedly started. This may cause inconveniences such as a wheel whose tread has been changed interfering with surrounding objects.

Japanese Patent No. 3651194

  The present invention has been made in view of the above situation, and the problem to be solved is that when the engine is stopped while the tread is being changed and then restarted, the tread is unexpectedly started. It is to provide a work vehicle that can be controlled so as not to be changed.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

That is, according to the first aspect, the tread includes a start / stop means capable of turning on the power of the device and starting the engine by the turning-on operation, and turning off the power of the device and stopping the engine by the turning-off operation. The hydraulic actuator to be changed, the setting operation unit for performing setting operations relating to the aircraft, the sensor for detecting the current value of the tread, and the current value of the tread are set to the setting values set by the setting operation unit. A control device capable of controlling the drive of the actuator, wherein the control device is such that the airframe is running and the actual rotational speed of the engine is a predetermined value. Only in the above case, the tread holding mode for controlling the drive of the actuator so that the current value of the tread becomes the set value can be executed. In the case where the current value of the tread after the start and stop means is switching operation during which the actuator is driven such that the set value, the starting and stopping means is input operation again, the current value of the tread Even if it is different from the set value, the interruption mode in which the actuator is not driven is executed.

  According to a second aspect of the present invention, when a predetermined operation of the setting operation unit is performed during the execution of the interruption mode, the control device sets a current value of the tread when the operation is performed as a setting value of the tread. At the same time, the interruption mode is terminated.

According to a third aspect of the present invention, when the size of a wheel mounted on the fuselage is input by the setting operation unit, the control device can change the set value of the tread only within a range suitable for the size of the wheel. Is.

  As effects of the present invention, the following effects can be obtained.

  According to the first aspect of the present invention, when the engine or the like is stopped while the tread is being changed and then restarted, the tread can be prevented from being changed unexpectedly.

  According to the second aspect, by setting the current value of the tread as a set value when the interruption mode is ended, it is possible to prevent the tread from being changed unexpectedly after the interruption mode ends.

According to the third aspect of the present invention, it is possible to prevent an inappropriate value from being set as a tread setting value due to an operator's erroneous operation .

The side view of the tractor concerning one embodiment of the present invention. The right front perspective view which showed the rear axle mechanism. Similarly, a left front perspective view. Schematic which showed the structure for changing a tread. The hydraulic circuit diagram which showed the hydraulic circuit regarding the change of a tread. The block diagram which showed the structure of the control mechanism regarding the change of a tread. The figure which showed the submeter by which various setting screens were displayed. The control mode transition diagram which showed the mode of control mode transition. The flowchart which showed the process in a tread holding | maintenance mode. (A) The figure which showed the mode of selection operation in various setting screens. (B) The figure which showed the tread setting screen. (A) The figure which showed a mode that the setting value of a tread was changed. (B) The figure which showed a mode that the setting value of a tread was decided. (A) The figure which showed a mode that the reduction | decrease of the setting value of the tread was once stopped. (B) The figure which showed a mode that the symbol which calls attention regarding the size of a wheel was displayed. The flowchart which showed the process in tread change mode. (A) The figure which showed the display content of the submeter during the change of a tread. (B) The figure which showed the submeter which displayed the notification screen. The flowchart which showed the process in a tread interruption mode. (A) The figure which showed a mode that the present value of the tread was displayed in the submeter which concerns on a modification. (B) The figure which showed a mode that the setting value of the tread was displayed similarly.

  In the following description, the directions indicated by the arrows in the figure are defined as the vertical direction, the front-rear direction, and the left-right direction, respectively.

  First, the overall configuration of a tractor 1 according to an embodiment of a work vehicle according to the present invention will be described with reference to FIG.

  In addition, in this embodiment, although the tractor 1 is illustrated as a working vehicle, this invention is not limited to this. That is, the work vehicle may be other agricultural vehicles, construction vehicles, industrial vehicles, or the like.

  The tractor 1 mainly includes a body frame 2, front wheels 3 and 3, a rear axle mechanism 4, a rear wheel (left rear wheel 5L and right rear wheel 5R), an engine 6, a bonnet 7, a transmission 8, a steering wheel 9, and a seat 10. And a cabin 11.

The body frame 2 is arranged with its longitudinal direction as the front-rear direction. The front part of the body frame 2 is supported by a pair of left and right front wheels 3 through a front axle mechanism (not shown). The rear part of the body frame 2 is supported by a pair of left and right rear wheels (a left rear wheel 5L and a right rear wheel 5R) via a rear axle mechanism 4.
An engine 6 is provided at the front of the body frame 2. The engine 6 is covered with a hood 7. A transmission 8 housed in a transmission case 8a is provided at the rear of the body frame 2.

  The power of the engine 6 can be transmitted to the front wheels 3 and 3 via the front axle mechanism after being shifted by the transmission 8 and can be transmitted to the rear wheels via the rear axle mechanism 4. The front wheels 3 and 3 and the rear wheels are rotationally driven by the power of the engine 6, and the tractor 1 travels.

  A driving operation unit including a steering wheel 9, a transmission operation tool (not shown), a seat 10, and the like is provided from the midway part to the rear part of the machine body frame 2 and is covered with the cabin 11. The steering wheel 9 can steer the tractor 1 by adjusting (changing) the turning angle of the pair of left and right front wheels 3 and 3 according to the amount of rotation operation.

  The above-described rear axle mechanism 4 is configured to be able to change the tread that is the distance between the centers of the pair of left and right rear wheels (the left rear wheel 5L and the right rear wheel 5R). Below, the structure (especially structure regarding the change of a tread) of the rear axle mechanism 4 is demonstrated. Since the rear axle mechanism 4 has a substantially symmetrical configuration on the left and right, only the configuration on the left side of the rear axle mechanism 4 will be described below.

  The rear axle mechanism 4 shown in FIGS. 2 to 4 transmits the power from the engine 6 to the left rear wheel 5L, and allows the tread of the left rear wheel 5L and the right rear wheel 5R to be changed. The rear axle mechanism 4 mainly includes a rear axle case 22, a sliding case 24, a left tread cylinder 26L, a rear axle 28, and a left tread detection mechanism 30.

  The rear axle case 22 is a substantially box-shaped member in which a member for power transmission can be disposed. The rear axle case 22 is attached to the left side surface of the transmission case 8a.

  The sliding case 24 is a substantially box-shaped member in which a member for power transmission can be disposed. The sliding case 24 is disposed on the left side of the rear axle case 22. The right end portion of the sliding case 24 is slidably inserted into the left side surface of the rear axle case 22.

  The left tread cylinder 26L is a hydraulic cylinder that can be expanded and contracted by hydraulic pressure. The left tread cylinder 26L is arranged with its longitudinal direction directed in the left-right direction. One end (right end) of the left tread cylinder 26L is connected to the rear axle case 22, and the other end (left end) is connected to the sliding case 24.

  The rear axle 28 transmits the driving force from the transmission 8 to the left rear wheel 5L. The rear axle 28 is arranged with its longitudinal direction directed in the left-right direction. One end of the rear axle 28 is rotatably supported by the sliding case 24, and the other end is fixed to the left rear wheel 5L. The power from the transmission 8 is transmitted to the rear axle 28 via a power transmission member (shaft, gear, etc.) disposed in the rear axle case 22 and the sliding case 24.

  The left tread detection mechanism 30 is for detecting the current value of the tread of the rear wheel. The left tread detection mechanism 30 mainly includes a support body 32, a left tread sensor 34L, a link mechanism 36, and a cover body 38.

  The support body 32 is a substantially rectangular parallelepiped member formed by combining a plurality of plate materials and the like. The support body 32 is fixed to the upper surface of the rear axle case 22.

  The left tread sensor 34L is a sensor for detecting the current value of the tread of the rear wheel. The left tread sensor 34L is configured by a rotary (rotary) potentiometer capable of detecting a rotation angle. The left tread sensor 34L is fixed to the front side surface of the support 32.

  The link mechanism 36 is for transmitting the position of the sliding case 24 relative to the rear axle case 22 to the left tread sensor 34L. The link mechanism 36 is configured by combining a plate-like member and a rod-like member. One end of the link mechanism 36 is connected to the detection unit of the left tread sensor 34 </ b> L, and the other end is connected to the sliding case 24.

  The cover body 38 is for protecting the structural member (particularly the left tread sensor 34L) of the left tread detection mechanism 30. The cover body 38 is formed by combining a plurality of plate materials and the like. The cover body 38 is fixed to the front portion of the support body 32 so as to cover the left tread sensor 34L from the front.

  For convenience of explanation, the cover body 38 is not shown in FIG. In FIG. 3, the left tread sensor 34 </ b> L is not visible due to the cover body 38.

  In the rear axle mechanism 4 configured as described above, when the left tread cylinder 26L expands and contracts, the sliding case 24 slides in the left-right direction with respect to the rear axle case 22. In this way, the tread of the pair of left and right rear wheels is changed.

  Further, when the sliding case 24 slides with respect to the rear axle case 22, the movement is transmitted to the left tread sensor 34L via the link mechanism 36. In this way, the position of the sliding case 24 relative to the rear axle case 22 can be detected, and consequently the current value of the tread of the pair of left and right rear wheels can be detected.

The rear axle mechanism 4 configured as described above is similarly provided on the right side of the airframe so as to be substantially symmetrical. In the rear axle mechanism 4 provided on the right side of the fuselage, members corresponding to the left tread cylinder 26L and the left tread sensor 34L described above are referred to as a right tread cylinder 26R (see FIG. 5) and a right tread sensor 34R (see FIG. 5), respectively. 6).
In the present embodiment, the left tread cylinder 26L and the right tread cylinder 26R are used as actuators. In the present embodiment, the left tread sensor 34L and the right tread sensor 34R are used as sensors.

  Next, a hydraulic circuit relating to tread change will be described.

  As shown in FIGS. 4 and 5, the hydraulic circuit related to the tread change is mainly configured by the hydraulic pump 40, the control valve 42, the left tread cylinder 26 </ b> L, and the right tread cylinder 26 </ b> R.

  The hydraulic pump 40 is for pumping hydraulic oil. The hydraulic pump 40 is driven by the engine 6 and sucks the hydraulic oil in the transmission case 8 a and pumps it to the control valve 42.

  The control valve 42 is a valve group for controlling the expansion / contraction operation of the left tread cylinder 26L and the right tread cylinder 26R. The control valve 42 mainly includes a left tread valve 44L and a right tread valve 44R.

  The left tread valve 44L is an electromagnetic valve for controlling the expansion / contraction operation of the left tread cylinder 26L. The left tread valve 44L includes a left extension solenoid 44La and a left contraction solenoid 44Lb.

  When both the left extension solenoid 44La and the left contraction solenoid 44Lb are not excited, the left tread valve 44L holds the hydraulic oil that is held in the neutral position and pumped from the hydraulic pump 40 to the right tread valve. invite. In this case, the left tread cylinder 26L is not driven.

  When the left extension side solenoid 44La is excited, the left tread valve 44L guides the operating oil pressure-switched from the hydraulic pump 40 to the bottom side oil chamber of the left tread cylinder 26L when the left extension side solenoid 44La is excited. As a result, the left tread cylinder 26L extends.

  When the left contraction side solenoid 44Lb is excited, the left tread valve 44L guides hydraulic oil pressure-fed from the hydraulic pump 40 to the rod side oil chamber of the left tread cylinder 26L when the left contraction solenoid 44Lb is excited. As a result, the left tread cylinder 26L is reduced.

  The right tread valve 44R is an electromagnetic valve for controlling the expansion / contraction operation of the right tread cylinder 26R. The right tread valve 44R includes a right extension solenoid 44Ra and a right contraction solenoid 44Rb.

  The right tread valve 44R is held in a neutral position and pumped from the hydraulic pump 40 via the left tread valve 44L when neither the right extension solenoid 44Ra nor the right contraction solenoid 44Rb is excited. The hydraulic oil is returned to the transmission case 8a. In this case, the right tread cylinder 26R is not driven.

  The right tread valve 44R is switched in position when the right extension solenoid 44Ra is excited, and the hydraulic oil pumped from the hydraulic pump 40 via the left tread valve 44L is supplied to the bottom side of the right tread cylinder 26R. Guide to the oil chamber. As a result, the right tread cylinder 26R extends.

  The right tread valve 44R is switched in position when the right contraction solenoid 44Rb is excited, and the hydraulic oil pumped from the hydraulic pump 40 via the left tread valve 44L is supplied to the rod side of the right tread cylinder 26R. Guide to the oil chamber. As a result, the right tread cylinder 26R is reduced.

  Thus, the left tread valve 44L and the right tread valve 44R are connected in series so that the hydraulic oil from the hydraulic pump 40 is sequentially supplied to the left tread valve 44L and the right tread valve 44R. .

  Next, a control mechanism related to tread change will be described.

  As shown in FIGS. 4 and 6, the control mechanism related to tread change is mainly the left tread sensor 34L, right tread sensor 34R, key switch 52, axle rotation sensor 54, crank position sensor 56, left extension side solenoid 44La, left The contraction side solenoid 44Lb, the right extension side solenoid 44Ra, the right contraction side solenoid 44Rb, the buzzer 58, the submeter 60, and the ECU 100 are configured.

  The left tread sensor 34L and the right tread sensor 34R are sensors for detecting the current value of the tread of the rear wheel as described above.

The key switch 52 can be operated by inserting a predetermined key. When the key switch 52 is turned on, the power of each device of the tractor 1 can be turned on and the engine 6 can be started. The key switch 52 can be turned off and the engine 6 can be stopped by turning off the key switch 52. The key switch 52 is disposed below the steering wheel 9 of the tractor 1 (see FIG. 1).
In the present embodiment, the key switch 52 is used as the start / stop means.

  The axle rotation sensor 54 detects the drive speed in the power transmission path from the engine 6 to the drive wheels (in this embodiment, the rear wheels that are always driven). The axle rotation sensor 54 is provided on the axle that transmits power to the rear wheels of the tractor 1 and can detect the driving speed of the axle (see FIG. 1).

  The crank position sensor 56 detects the rotational position of the flywheel of the engine 6 and thus detects the actual rotational speed (shaft rotational speed) of the engine 6. The crank position sensor 56 is provided in the vicinity of the engine 6 (more specifically, the flywheel of the engine 6).

  The left extension solenoid 44La, the left contraction solenoid 44Lb, the right extension solenoid 44Ra, and the right contraction solenoid 44Rb are for switching the positions of the left tread valve 44L and the right tread valve 44R as described above.

  The buzzer 58 is for notifying an operator of a predetermined situation by making a sound. The buzzer 58 is disposed in the vicinity of the steering wheel 9 of the tractor 1 (see FIG. 1).

  The submeter 60 is used for performing setting operation regarding the tractor 1 and notifying the operator of information regarding the tractor 1. The sub meter 60 is disposed on the side of the seat 10 separately from the meter panel disposed in front of the seat 10 of the tractor 1 (see FIG. 1). The submeter 60 mainly includes a liquid crystal display unit 61 and an operation unit 62.

The liquid crystal display unit 61 shown in FIG. 7 is for notifying an operator of information related to the tractor 1. The liquid crystal display 61 is formed in a substantially rectangular shape and is disposed on the submeter 60.
In the present embodiment, the liquid crystal display unit 61 of the submeter 60 is used as the display unit.

The operation unit 62 is for performing a setting operation related to the tractor 1. The operation unit 62 includes a plurality of buttons (menu button 62a, first button 62b, second button 62c, third button 62d, and fourth button 62e). The plurality of buttons of the operation unit 62 are arranged in a line below the liquid crystal display unit 61.
In the present embodiment, the operation unit 62 of the submeter 60 is used as the setting operation unit.

The ECU 100 shown in FIGS. 4 and 6 manages information related to the tractor 1 and controls the operation of each connected device. The ECU 100 is disposed in the cabin 11 of the tractor 1 (see FIG. 1). The ECU 100 includes a storage unit, an arithmetic processing unit, and the like. The ECU 100 stores a program for controlling each device of the tractor 1 and various data.
In the present embodiment, the ECU 100 is used as the control device.

The ECU 100 is connected to the left tread sensor 34L and the right tread sensor 34R, and can receive information about detection values of the left tread sensor 34L and the right tread sensor 34R. The ECU 100 can calculate the current value of the tread of the rear wheel based on the information.
The ECU 100 is connected to the key switch 52 and can receive information about the operation of the key switch 52.
The ECU 100 is connected to the axle rotation sensor 54 and can receive information on the driving speed in the power transmission path from the engine 6 to the rear wheels. The ECU 100 can calculate the speed (vehicle speed) of the tractor 1 based on the information.
ECU 100 is connected to crank position sensor 56 and can receive information about the rotational position of the flywheel of engine 6. ECU 100 can calculate the actual rotational speed of engine 6 based on the information.

The ECU 100 is connected to the left extension solenoid 44La, the left contraction solenoid 44Lb, the right extension solenoid 44Ra, and the right contraction solenoid 44Rb, respectively, and can control the operation (excitation) of each solenoid.
The ECU 100 is connected to the buzzer 58 and can control the operation of the buzzer 58.

The ECU 100 is connected to the submeter 60 and can display various information on the liquid crystal display unit 61 of the submeter 60.
Further, the ECU 100 can receive information about the operation of the operation unit 62 of the submeter 60.

  Below, the control regarding the change of a tread in the tractor 1 comprised as mentioned above is demonstrated. Control regarding the change of the tread is performed by the ECU 100 according to a predetermined program.

  As shown in FIG. 8, the ECU 100 mainly includes a tread holding mode M1, a tread change mode M2, a tread interruption mode M3, and a tread fine adjustment mode M4 as control modes related to tread change. First, these control modes will be briefly described.

  The tread holding mode M1 is a mode in which the current value (current actual value) of the tread of the tractor 1 is held at the set value set by the operator. In the tread holding mode M1, the ECU 100 holds the current value of the tread at the set value (more specifically, within the range of the set value from the set value) when the current value of the tread deviates from the set value by a larger value. In this manner, each solenoid (left extension side solenoid 44La and the like) is controlled.

  The tread change mode M2 is a mode in which the current value of the tread is changed to the set value when the set value of the tread is changed. In the tread change mode M2, when the tread set value is changed, the ECU 100 controls each solenoid so that the current value of the tread becomes the set value.

The tread interruption mode M3 is a mode that is executed when the key switch 52 is turned off during the tread change mode M2 to interrupt the tread change mode M2 and then the key switch 52 is turned on. In the tread interruption mode M3, the ECU 100 displays on the submeter 60 that the tread change mode M2 has been interrupted, and continues the tread interruption mode M3 until a predetermined operation is performed.
In the present embodiment, a tread interruption mode M3 is provided as the interruption mode.

  The tread fine adjustment mode M4 is a mode in which the ECU 100 automatically performs fine adjustment of the left tread sensor 34L and the right tread sensor 34R.

  Below, the detail of each control mode and the transition between control modes are demonstrated in detail.

  First, the process in the tread holding mode M1 will be described with reference to FIG.

In step S102, the ECU 100 determines whether or not the key switch 52 has been turned off.
When the key switch 52 is turned off, the ECU 100 proceeds to step S114. That is, the set value of the tread at that time is stored, and the key switch is turned off (the power of each device of the tractor 1 is turned off and the engine 6 is stopped) M5 (see FIG. 8).
When the key switch 52 is not turned off, the ECU 100 proceeds to step S104.

In step S104, the ECU 100 determines whether or not a “Set” symbol 61m described later has been selected.
If the “Set” symbol 61m is selected, the ECU 100 proceeds to step S116. That is, the transition is made to the tread change mode M2.
If the “Set” symbol 61m is not selected, the ECU 100 proceeds to step S106.

In step S106, the ECU 100 determines whether or not a fine adjustment condition is satisfied. The “fine adjustment condition” means that a specific operation preset as a condition for transitioning to the tread fine adjustment mode M4 is performed.
If the ECU 100 determines that the fine adjustment condition is satisfied, the ECU 100 proceeds to step S118. That is, the state transits to the tread fine adjustment mode M4.
If the ECU 100 determines that the fine adjustment condition is not satisfied, the ECU 100 proceeds to step S108.

In step S108, the ECU 100 determines whether or not the current value of the tread is significantly deviated from a predetermined value from the set value, in other words, whether or not the current value of the tread is within a predetermined value range from the set value. Determine.
When the ECU 100 determines that the current value of the tread is within a predetermined value range from the set value, the ECU 100 repeats the process of the tread holding mode M1.
If the ECU 100 determines that the current value of the tread is not within the predetermined value range from the set value, the ECU 100 proceeds to step S110.

  In step S110, the ECU 100 determines whether or not a solenoid output condition is satisfied.

  Here, the “solenoid output condition” is a condition that must be satisfied when the ECU 100 controls (excites) the operation of each solenoid. The solenoid output conditions are specifically two points: (1) the tractor 1 is traveling (the speed is greater than 0), and (2) the actual rotational speed of the engine 6 is equal to or greater than a predetermined value. It is.

  By satisfying the condition (1), the tread is changed only while the tractor 1 is traveling. As a result, it is possible to prevent the tread from being changed while the tractor 1 having a large friction between the wheel and the ground is stopped, and applying a load to the wheel and other members (and thus causing damage). The ECU 100 calculates the speed of the tractor 1 based on the detection value of the axle rotation sensor 54 and determines whether or not the tractor 1 is traveling.

  Further, by satisfying the condition (2), the left tread valve 44L or the right tread valve 44R is operated only when the engine 6 is driven at a predetermined speed or higher. As a result, the position of the left tread valve 44L and the like is changed when the engine 6 where the hydraulic pump 40 (see FIG. 5) is not sufficiently driven is stopped, and the hydraulic oil flows out of the left tread cylinder 26L and the like, so that an accurate tread is obtained. Can not be changed. The ECU 100 calculates the shaft rotational speed of the engine 6 based on the detection value of the crank position sensor 56, and determines whether or not the engine 6 is driven at a predetermined rotational speed or higher.

When it is determined that the solenoid output condition is not satisfied, the ECU 100 repeats the process of the tread holding mode M1.
If it is determined that the solenoid output condition is satisfied, the ECU 100 proceeds to step S112.

  In step S112, the ECU 100 controls each solenoid so that the current value of the tread falls within the predetermined value range from the set value.

  Here, the ECU 100 performs control so that two or more solenoids are not excited simultaneously. For example, when it is necessary to excite both the solenoid of the left tread valve 44L and the right tread valve 44R (see FIG. 5), the excitation of the right tread valve 44R is prioritized. To do. By exciting each solenoid in this way, the left tread valve 44L and the right tread valve 44R connected in series can be operated accurately, and the tread can be changed reliably.

  The ECU 100 controls each solenoid so that the lengths of the left tread cylinder 26L and the right tread cylinder 26R are the same. Thereby, it can hold | maintain so that the distance from the left-right center of the body of the tractor 1 to the left and right rear wheels may become the same, respectively, and the attitude | position of the tractor 1 can be stabilized.

  The ECU 100 repeats the process in the tread holding mode M1 after performing the process.

  In this way, in the tread holding mode M1, the ECU 100 controls the operation of each solenoid so that the current value of the tread is held within a predetermined value range from the set value (step S108). As a result, the tread of the tractor 1 is held at a set value (more precisely, a value close to the set value), and work and traveling on a desired tread can be performed.

  Next, the operation and display of the submeter 60 at the time of transition from the tread holding mode M1 to the tread change mode M2 (step S104 and step S116) will be described in detail.

  In the tread holding mode M1, the ECU 100 displays information related to the tractor 1 (for example, the speed (vehicle speed) of the tractor 1) on the liquid crystal display unit 61 of the submeter 60. The information to be displayed can be arbitrarily selected in advance by an operator.

  In this state, when the operator keeps pressing the menu button 62a for a predetermined time or longer (hereinafter simply referred to as “long press”), the ECU 100 switches the liquid crystal display unit 61 to various setting screens shown in FIG. The various setting screens are screens for the operator to perform setting operations regarding the tractor 1.

  Here, symbol 61a is the setting of the circumference of the wheel, symbol 61b is the setting of the width of the work machine attached to the tractor 1, symbol 61c is the setting of time, symbol 61d is the setting relating to the measurement of the travel distance, 61e is a setting relating to the control of the slip ratio of the tractor 1, 61f is a setting relating to the work history of the tractor 1, 61g is a setting of control for interlocking the raising / lowering of the work implement attached to the tractor 1 and the vehicle speed, and 61h is This is selected when each tread is set.

  When the operator changes the tread of the tractor 1, as shown in FIG. 10A, the operator presses the second button 62b or the third button 62d a plurality of times to move the cursor to the symbol 61h, and presses the fourth button 62e. The symbol 61h is selected. When the symbol 61h is selected, the ECU 100 switches the liquid crystal display unit 61 to a tread setting screen shown in FIG. The tread setting screen is a screen for changing the tread setting value of the tractor 1.

  On the tread setting screen, the ECU 100 causes the current value 61 j and the set value 61 k of the tread of the tractor 1 to be displayed at the substantially central portion of the liquid crystal display unit 61 at the same time. As shown in FIG. 11A, the operator moves the cursor to the set value 61k, presses the first button 62b or the second button 62c, and arbitrarily changes the value of the set value 61k. At this time, the set value 61k can be increased or decreased quickly and continuously by long pressing the first button 62b or the second button 62c. In FIG. 11A, the setting value 61k is changed to 1400 (mm).

  Note that the value of the set value 61k can be changed to a predetermined number of steps or can be changed steplessly.

  After changing the set value 61k to a desired value, the operator presses the third button 62d to place the cursor on the “Set” symbol 61m and presses the fourth button 62e, as shown in FIG. 11B. The “Set” symbol 61m is selected, and the set value 61k is determined.

  In this way, as described in step S104 and step S116, the ECU 100 transitions from the tread holding mode M1 to the tread change mode M2.

  In this tread setting screen, when the first button 62b is pressed (or long pressed) to decrease the tread setting value 61k, the ECU 100 sets a predetermined value (see FIG. 12A). In the present embodiment, the decrease of the set value 61k is temporarily stopped at 1320 (mm). That is, in the operation of pressing the first button 62b (or the operation of long pressing), the set value 61k cannot be decreased any more. The ECU 100 further decreases the set value 61k only when the button (first button 62b) is once released and then pressed again for a long time.

  This is because when the tread is set to be less than the predetermined value (1320 (mm)), depending on the size (type) of the wheel (rear wheel), the body of the tractor 1 and the rear wheel may interfere with each other. This is a measure for preventing easy setting below the predetermined value.

  When the first button 62b is pressed for a long time and the set value 61k is decreased below the predetermined value, as shown in FIG. 12B, the ECU 100 causes the tractor 1 with the tread set to be less than the predetermined value. The size of a wheel that can be used (mounted) without interfering with the aircraft is displayed as a symbol 61n.

  In this way, when changing to a tread setting value that may cause interference between the wheels and the body of the tractor 1, the operator releases a predetermined operation different from the previous setting operation (the button is released once and then the button is pressed again). Need to be held down). Further, when changing to such a tread set value, the ECU 100 displays the symbol 61n to notify the operator of the usable wheel size. In this way, it is possible to alert the worker about the size of the wheel and prevent the occurrence of interference between the wheel and the airframe.

  In the present embodiment, the predetermined operation is required only when the set value of the tread is set to be less than the predetermined value. However, the present invention is not limited to this. For example, when the set value of the tread is set larger than a predetermined value, it is possible to adopt a configuration that requires the same operation. Thus, when changing the tread to a large value, the operator can be alerted so that contact between the wheels and obstacles around the tractor 1 does not occur.

  As described above, when the tread setting value is changed outside the predetermined range (a value less than the predetermined value or a value larger than the predetermined value), the predetermined value is different from the case where the tread setting value is changed within the predetermined range. It is possible to adopt a configuration that requires an operation, and the predetermined range can be arbitrarily set in advance according to the model of the tractor 1, the work content, and the like.

  Next, processing in the tread change mode M2 will be described with reference to FIGS.

In step S202, the ECU 100 determines whether or not the key switch 52 has been turned off.
When the key switch 52 is turned off, the ECU 100 proceeds to step S212.
If the key switch 52 is not turned off, the ECU 100 proceeds to step S204.

  In step S204, the ECU 100 determines whether or not the “CANCEL” symbol 61p is selected.

Here, as shown in FIG. 14A, in the tread change mode M2, the ECU 100 displays the “CANCEL” symbol 61p on the liquid crystal display unit 61 of the submeter 60. The “CANCEL” symbol 61p is for stopping the driving of the left tread cylinder 26L and the right tread cylinder 26R at an arbitrary timing.
The operator can press the third button 62d to move the cursor to the “CANCEL” symbol 61p, and press the fourth button 62e to select the “CANCEL” symbol 61p.

If the ECU 100 determines that the “CANCEL” symbol 61p has been selected, the ECU 100 proceeds to step S216.
If the ECU 100 determines that the “CANCEL” symbol 61p is not selected, the ECU 100 proceeds to step S206.

In step S206, the ECU 100 determines whether or not the current value of the tread is significantly deviated from a predetermined value from the set value, in other words, whether or not the current value of the tread is within a predetermined value range from the set value. Determine.
If the ECU 100 determines that the current value of the tread is within a predetermined value range from the set value, the ECU 100 proceeds to step S218. In other words, in this case, the ECU 100 makes a sound from the buzzer 58 to notify the worker and makes a transition to the tread holding mode M1.
If the ECU 100 determines that the current value of the tread is not within the predetermined value range from the set value, the ECU 100 proceeds to step S208.

In step S208, the ECU 100 determines whether or not a solenoid output condition is satisfied. Since the solenoid output condition is the same as that in the tread holding mode M1, description thereof is omitted.
When ECU 100 determines that the solenoid output condition is not satisfied, ECU 100 repeats the process of tread change mode M2.
If it is determined that the solenoid output condition is satisfied, the ECU 100 proceeds to step S210.

  In step S210, the ECU 100 controls each solenoid so that the current value of the tread changes in a direction approaching the set value.

  At this time, as shown in FIG. 14A, the ECU 100 causes the liquid crystal display unit 61 of the submeter 60 to simultaneously display the current value 61j of the tread and the set value 61k side by side. Accordingly, it is possible to easily notify the operator of how much the current tread value (current value) is with respect to the set value. Further, the ECU 100 blinks the display of the current value 61j. This can inform the operator that the tread is currently being changed.

  The ECU 100 repeats the process in the tread change mode M2 after performing the process.

In step S212, which has shifted from step S202, the ECU 100 stores a value of “1” as the interruption flag.
Here, the “interruption flag” is used to determine whether or not the key switch 52 is turned off during the tread change. Normally, a value “0” is stored in the interruption flag.
After performing the processing, the ECU 100 proceeds to step S214. That is, the state transits to the key switch OFF state M5.

In step S216, which has shifted from step S204, the ECU 100 sets (stores) the current value of the tread when the “CANCEL” symbol 61p is selected as a set value.
After the ECU 100 performs the process, the ECU 100 proceeds to step S218. That is, the state transits to the tread holding mode M1.

  In this way, in the tread change mode M2, the ECU 100 repeatedly controls the operation of each solenoid (step S210) so that the current value of the tread becomes a set value (more precisely, a value close to the set value) ( Step S206) Change. When the change of the tread is completed (step S206), the ECU 100 shifts the control mode to the tread holding mode M1 (step S218), and starts control to hold the tread at the set value. Further, when the key switch 52 is turned off while the tread change mode M2 is being executed, that is, while the tread of the tractor 1 is changed to the set value (step S202), the ECU 100 serves as an interruption flag. A value of 1 is stored (step S212), and a transition is made to the key switch OFF state M5 (step S214).

  Next, a state when the key switch OFF state M5 is changed to the tread holding mode M1 or the tread interruption mode M3 will be described.

  As shown in FIG. 8, the ECU 100 operates when the key switch 52 is turned off in the tread holding mode M1 (step S102 in FIG. 9), and when the key switch 52 is turned off in the tread change mode M2 (FIG. 13). In step S202), when the key switch 52 is turned off in the tread interruption mode M3 described later (step S302 in FIG. 15), or in the tread fine adjustment mode M4 (detailed description is omitted), the key switch 52 is turned off. In this case, the state transits to the key switch OFF state M5.

  When the key switch 52 is turned on in the key switch OFF state M5, the ECU 100 transits from the key switch OFF state M5 to the initialization processing state M6.

  In the initialization process state M6, the ECU 100 reads the stored tread setting value and the value of the interruption flag. Then, when the value of the interruption flag is 0, the ECU 100 transitions to the tread holding mode M1. Further, the ECU 100 operates the key switch 52 to be turned off when the value of the interruption flag is 1, that is, while the tread of the tractor 1 is changed to the set value in the previous tread change mode M2. In this case, the state transits to the tread interruption mode M3.

  Next, processing in the tread interruption mode M3 will be described with reference to FIGS.

In step S302, the ECU 100 determines whether or not the key switch 52 has been turned off.
When the key switch 52 is turned off, the ECU 100 proceeds to step S308. That is, the state transits to the key switch OFF state M5 (see FIG. 8).
If the key switch 52 is not turned off, the ECU 100 proceeds to step S304.

  In step S304, the ECU 100 displays a notification screen 61q on the liquid crystal display unit 61 of the submeter 60.

  Here, the notification screen 61q is a screen for notifying the worker that the tread suspension mode M3 is currently being executed, as shown in FIG. 14B. The notification screen 61q is displayed over substantially the entire area of the liquid crystal display unit 61, and other information (for example, menus of various setting screens as shown in FIG. 7 and current values 61j of treads as shown in FIG. 14A). And the set value 61k, etc.) are not displayed at the same time. Thus, by displaying only the notification screen 61q on the liquid crystal display unit 61, it is possible to more reliably notify the operator that the tread suspension mode M3 is being executed.

  After performing the processing, the ECU 100 proceeds to step S306.

In step S306, the ECU 100 determines whether or not the fourth button 62e has been pressed.
If the ECU 100 determines that the fourth button 62e has been pressed, the ECU 100 proceeds to step S310.
When it is determined that the fourth button 62e is not pressed, the ECU 100 repeats the process of the tread interruption mode M3.

In step S310, the ECU 100 sets the current value of the tread when the fourth button 62e is pressed and operated as a setting value.
After performing the processing, ECU 100 proceeds to step S312. That is, the state transits to the tread holding mode M1.

  Thus, in the tread interruption mode M3, the ECU 100 continues to display only the notification screen 61q on the submeter 60 (step S304) until the fourth button 62e is pressed (step S306). Then, the operator sees the notification screen 61q and that the tread suspension mode M3 is currently being executed, that is, the tread of the tractor 1 has been changed to the set value in the previous tread change mode M2. It can be recognized that the key switch 52 has been turned off.

  Further, the operator can press the fourth button 62e (step S306) to end the tread interruption mode M3 and shift to the tread holding mode M1 (step S312). Here, since the tread when the fourth button 62e is pressed is newly set as a set value (step S310), the tread is prevented from being changed unexpectedly immediately after the transition to the tread holding mode M1. be able to. At this time, if the lengths of the left tread cylinder 26L and the right tread cylinder 26R are different for some reason (for example, leakage of hydraulic oil from each cylinder in the key switch OFF state M5), the tread holding mode M1 In step S112, the left and right cylinders are adjusted again to have the same length (see step S112).

  Further, in the tread interruption mode M3, even if the current value of the tread is different from the set value, processing (control) for changing the tread so as to become the set value is not performed. Thereby, it is possible to prevent (check) the tread from being changed unexpectedly.

As described above, the tractor 1 (work vehicle) according to the present embodiment is
A key switch 52 (start / stop means) capable of turning on the power of the device and starting the engine 6 by turning on and turning off the power of the device and stopping the engine 6 by turning off;
Actuators for changing the tread (left tread cylinder 26L and right tread cylinder 26R);
An operation unit 62 (setting operation unit) of the submeter 60 for performing a setting operation related to the airframe;
Sensors (left tread sensor 34L and right tread sensor 34R) for detecting the current value of the tread;
An ECU 100 (control device) capable of controlling the drive of the actuator so that the current value of the tread becomes a set value set by the operation unit 62;
A tractor 1 comprising:
The ECU 100
When the key switch 52 is turned off after the key switch 52 is turned off while the actuator is being driven so that the current value of the tread becomes the set value, the current value of the tread is Even if it differs from the set value, the tread interruption mode M3 (interruption mode) in which the actuator is not driven is executed.
With this configuration, when the engine 6 is stopped while the tread is being changed and then restarted, the tread can be prevented from being changed unexpectedly.

Further, the ECU 100
When the pressing operation (predetermined operation) of the fourth button 62e of the operation unit 62 is performed during execution of the tread interruption mode M3, the current value of the tread at the time of the operation is set as a setting value of the tread. The tread interruption mode M3 is terminated.
By configuring in this way, by setting the current value of the tread as a set value when the tread suspension mode is finished, it is possible to prevent the tread from being changed unexpectedly after the tread suspension mode is finished. it can.

In addition, the tractor 1
It further comprises a liquid crystal display unit 61 (display unit) of the submeter 60 for notifying the operator of information related to the machine body,
The ECU 100
When the tread interruption mode M3 is being executed, only the fact that the tread interruption mode M3 is being executed (notification screen 61q) is displayed on the liquid crystal display unit 61, and other information is not displayed.
By configuring in this way, it is possible to more reliably notify the operator that the tread interruption mode M3 is being executed.

In addition, the tractor 1 according to the present embodiment is
A liquid crystal display unit 61 of a submeter 60 for notifying an operator of information related to the airframe;
The actuator for changing the tread;
An operation unit 62 of a submeter 60 for performing a setting operation relating to the airframe;
The sensor for detecting the current value of the tread;
An ECU 100 capable of controlling the drive of the actuator so that the current value of the tread becomes a set value set by the setting operation unit;
A tractor 1 comprising:
The ECU 100
The liquid crystal display unit 61 displays the current tread value 61j and the set value 61k.
By configuring in this way, the current value 61j and the set value 61k of the tread can be easily confirmed.

Further, the ECU 100
The liquid crystal display unit 61 displays the current tread value 61j and the set value 61k simultaneously.
With this configuration, the set value 61k and the current value 61j of the tread can be confirmed at the same time.

Further, the ECU 100
When the actuator is driven so that the current value of the tread becomes the set value, the current value 61j of the tread is blinked.
With this configuration, it can be easily confirmed that the tread is being changed.

Further, the ECU 100
When the tread set value 61k is changed to a value outside the predetermined range by the operation of the operation unit 62, it can be changed only when a predetermined operation different from the case of changing to a value within the predetermined range is performed,
The operator can be notified of the wheels that can be mounted on the fuselage changed to a tread outside the predetermined range.
By configuring in this way, it is possible to call the operator's attention by requesting a predetermined operation when changing the tread set value 61k to a value outside the predetermined range. In addition, the operator can easily check the wheels that can be mounted.

Further, the ECU 100
While driving the actuator so that the current value of the tread becomes the set value, a “CANCEL” symbol 61p (stop symbol) for stopping the driving of the actuator is displayed on the liquid crystal display unit 61.
When an operation of selecting the “CANCEL” symbol 61p is performed, the driving of the actuator is stopped.
With this configuration, the tread change can be stopped at any timing regardless of the tread set value 61k.

  In the present embodiment, the key switch 52 that can be operated by inserting a predetermined key is used as the start / stop means. However, the present invention is not limited to this, and various other operation tools (for example, It is also possible to use a push button or the like.

  In the present embodiment, the submeter 60 (the liquid crystal display unit 61 and the operation unit 62) is used as the setting operation unit and the display unit. However, the present invention is not limited to this, and for example, the setting operation unit and the display unit Can be configured as separate members, and the setting operation unit and the display unit can be configured integrally using a touch panel. In the present embodiment, buttons (menu button 62a, first button 62b, second button 62c, third button 62d, and fourth button 62e) are used in the setting operation unit, but the present invention is not limited to this. For example, the setting value of the tread displayed on the display unit can be changed using a dial.

  In this embodiment, the left tread cylinder 26L and the right tread cylinder 26R are used as actuators. However, the present invention is not limited to this, and the left and right sliding cases are connected by a single cylinder. Alternatively, other actuators (for example, a motor or the like) can be used as long as the tread can be changed.

  In the present embodiment, the ECU 100 is used as the control device. However, the present invention is not limited to this. For example, a plurality of ECUs (an ECU for controlling the engine 6 and a tread for controlling the engine 6) of the tractor 1 are controlled. It is also possible to use it as a control device in combination.

  In this embodiment, the rotary potentiometer (the left tread sensor 34L and the right tread sensor 34R) is used as a sensor. However, the present invention is not limited to this, and the tread of the tractor 1 can be detected. Any sensor can be used.

  In the present embodiment, when the tread setting value is changed outside the predetermined range (less than the predetermined value), the wheel size usable in the tread is displayed as the symbol 61n. (See FIG. 12B) For example, the size of the wheel mounted on the tractor 1 can be input in advance from the submeter 60, and the set value of the tread can be changed only to a range suitable for the size of the wheel. It is. In this way, by limiting the range of setting values that can be changed according to the wheel size, it is possible to prevent an inappropriate value from being set as a tread setting value due to an operator's erroneous operation.

  In this embodiment, a pair of left and right rear wheels (5L, 5R) are mounted. However, the present invention is not limited to this, and for example, a crawler type rear wheel may be mounted.

  Moreover, in this embodiment, although this control in left-right paired rear wheels (5L, 5R) was illustrated, this invention is not restricted to this, This control is implemented in a front wheel (3.3). Is also possible.

  In the present embodiment, the ECU 100 displays the current tread current value 61j and the set value 61k simultaneously on the liquid crystal display unit 61 (see FIG. 11 and the like), but the present invention is not limited to this. That is, as shown in FIG. 16, the current value 61j (FIG. 16 (a)) and the set value 61k (FIG. 16 (b)) can be displayed separately. In this case, the display of the current value 61j or the set value 61k can be switched by the operation of the operation unit 62.

1 Tractor (work vehicle)
6 Engine 26L Left tread cylinder (actuator)
26R Right tread cylinder (actuator)
34L Left tread sensor (sensor)
34R Right tread sensor (sensor)
52 Key switch (start / stop means)
60 Submeter 61 Liquid crystal display (display)
62 Operation section (setting operation section)
100 ECU (control device)

Claims (3)

A start / stop means capable of turning on the power of the device and starting the engine by turning on and turning off the power of the device and stopping the engine by turning off;
A hydraulic actuator that changes the tread;
A setting operation section for performing setting operations relating to the aircraft,
A sensor for detecting the current value of the tread;
A control device capable of controlling the drive of the actuator so that the current value of the tread becomes a set value set by the setting operation unit;
A work vehicle comprising:
The controller is
A tread hold mode that controls the drive of the actuator so that the current value of the tread becomes the set value can be executed only when the aircraft is running and the actual engine speed is greater than or equal to a predetermined value. And
When the start / stop means is turned on again after the start / stop means is turned off while the actuator is being driven so that the current value of the tread becomes the set value, the current value of the tread Even if it is different from the set value, it is characterized by executing an interrupt mode that does not drive the actuator,
Work vehicle. The controller is
When a predetermined operation of the setting operation unit is performed during execution of the interruption mode, the current value of the tread at the time of the operation is set as a setting value of the tread, and the interruption mode is ended. And
The work vehicle according to claim 1. The controller is
When the size of the wheel mounted on the fuselage is input by the setting operation unit, the setting value of the tread can be changed only to a range suitable for the size of the wheel ,
The work vehicle according to claim 1 or claim 2.

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