JP6822225B2 - Work vehicle - Google Patents

Description

The present invention relates to a work vehicle.

In a configuration in which one brake on the inside of the turning is automatically activated when the work vehicle is turning, a technique is known in which the braking force is weakly braked to prevent the surface of the field from being roughened (see Patent Document 1).

Japanese Unexamined Patent Publication No. 2001-151142

However, if the braking force of the automatic brake is weakened, the turning radius may become too large. In that case, the driver must step on the brake pedal corresponding to the inside of the turning to increase the braking force, which is troublesome to operate.

An object of the present invention is to provide a work vehicle capable of easily adjusting the braking force of a brake even if the braking force is insufficient, for example, when turning by an automatic brake.

The first invention is
With the running body
A pair of left and right rear wheel braking devices that can separately brake the pair of left and right rear wheels provided on the traveling vehicle body,
A pair of left and right brake pedals that operate the pair of left and right rear wheel brake devices,
A brake pressure setting switch that presets the brake pressure applied to the rear wheels on the inside of the turn via the rear wheel brake device corresponding to the rear wheels on the inside of the turn when the traveling vehicle body turns.
When the traveling vehicle body starts the turning, the control device that applies the brake pressure to the rear wheels inside the turning and the control device.
In the middle of the turning, the brake pressure changing unit for changing the preset brake pressure and the brake pressure changing unit
An elevating mechanism that elevates and elevates the work machine connected to the rear of the traveling vehicle body,
An elevating operation switch that operates the elevating mechanism ascending / descending,
With
The control device changes the preset brake pressure in the middle of the turning based on the output from the brake pressure changing unit.
The elevating operation switch also serves as the brake pressure changing unit.
While the traveling vehicle body is making the turn, the control device does not accept the operation command by the elevating operation switch as meaning the ascending / descending operation of the elevating mechanism, and the brake pressure changing unit does not accept the operation command. Accepted as the preset brake pressure change command, and while the traveling vehicle body is not making the turn, the operation command by the elevating operation switch means the ascending / descending operation of the elevating mechanism. It is a work vehicle characterized by being accepted as.
Further, the second invention of the present invention
The control device is the first work vehicle of the present invention, characterized in that the preset brake pressure is intermittently changed.
Moreover, the third invention of this invention
The control device is the first work vehicle of the present invention, characterized in that the preset brake pressure is continuously changed.
The first of inventions related to the present invention,
With the running body
A pair of left and right rear wheel braking devices that can separately brake the pair of left and right rear wheels provided on the traveling vehicle body,
A pair of left and right brake pedals that operate the pair of left and right rear wheel brake devices,
A brake pressure setting switch that presets the brake pressure applied to the rear wheels on the inside of the turn via the rear wheel brake device corresponding to the rear wheels on the inside of the turn when the traveling vehicle body turns.
When the traveling vehicle body starts the turning, the control device that applies the brake pressure to the rear wheels inside the turning and the control device.
In the middle of the turning, the brake pressure changing unit for changing the preset brake pressure and the brake pressure changing unit
With
The control device is a work vehicle characterized in that the preset brake pressure is changed during the turning based on the output from the brake pressure changing unit.

As a result, the brake pressure can be easily adjusted even if the brake pressure is insufficient, for example, when turning by the automatic brake.

The second calling relevant to the present invention Ming,
The control device, the intermittently change the brake pressure set in advance, it is first inventions for a working vehicle relating to the present invention, wherein.

Thus, in addition to the first inventions of effects associated with the present invention, intermittently it can change the brake pressure with a simple operation.

The third origination in the context of the present invention Ming,
The control device, the continuously changing the brake pressure set in advance, it is first inventions for a working vehicle relating to the present invention, wherein.

Thus, in addition to the first inventions of effects associated with the present invention, the brake pressure continuously may be changed by a simple operation.

The fourth of the origination in the context of the present invention Ming,
An elevating mechanism that elevates and elevates the work machine connected to the rear of the traveling vehicle body,
Equipped with an elevating operation switch for operating the ascending / descending of the elevating mechanism.
The elevating operation switch also serves as the brake pressure changing unit.
While the traveling vehicle body is making the turn, the control device does not accept the operation command by the elevating operation switch as meaning the ascending / descending operation of the elevating mechanism, and the brake pressure changing unit does not accept the operation command. Accepted as the preset brake pressure change command, and while the traveling vehicle body is not making the turn, the operation command by the elevating operation switch means the ascending / descending operation of the elevating mechanism. It is a work vehicle of the invention related to the present invention, which is any one of the first to third related to the present invention, characterized in that it is accepted as.

Thus, in addition to the effects of the present invention related to any one of the present invention of the first to third related to the invention, the lifting operation switch, since also functions braking pressure changing unit, new switches No need to add.

In addition, the fifth issued in connection with the present invention Ming,
With the running body
A pair of left and right rear wheel braking devices that can separately brake the pair of left and right rear wheels provided on the traveling vehicle body,
A brake pressure setting switch that presets the brake pressure applied to the rear wheels on the inside of the turn via the rear wheel brake device corresponding to the rear wheels on the inside of the turn when the traveling vehicle body turns.
When the traveling vehicle body starts the turning, the control device that applies the brake pressure to the rear wheels inside the turning and the control device.
A turning angular velocity sensor that detects a turning angular velocity during turning of the traveling vehicle body is provided.
When the control device determines that the turning angular velocity detected by the turning angular velocity sensor is smaller than a predetermined threshold value, the control device tends to increase the preset brake pressure during the turning. It is a work vehicle characterized by being changed.

As a result, even if the brake pressure is insufficient during turning by the automatic brake, the brake pressure can be automatically increased, so that appropriate turning can be performed and workability can be improved.

According to the present invention, it is possible to provide a work vehicle capable of easily adjusting the brake pressure even if the brake pressure is insufficient, for example, when turning by the automatic brake.

Overall left side view of the tractor according to the embodiment of the present invention Schematic perspective view of the steering wheel side from the driver's seat side of the tractor of the present embodiment. Perspective view around the elevating / lowering switching lever of the tractor of the present embodiment The figure which shows the meter panel of the tractor of this embodiment Perspective view showing various switches provided on the operation panel of the tractor of the present embodiment. Schematic diagram showing the power transmission mechanism in the tractor of the present embodiment and the hydraulic circuit in the automatic braking mechanism. The control block diagram of the tractor of this embodiment The schematic diagram which shows the change of the brake pressure of the automatic brake in the tractor of this embodiment (A): Schematic diagram showing an example of a pressure change in a configuration in which the default brake pressure P ₀ of the automatic brake is continuously increased by ΔP to change the brake pressure to P ₁ , (b): of the automatic brake. Schematic diagram showing an example of pressure change in a configuration in which the default brake pressure P ₀ is continuously reduced by ΔP to change the brake pressure to P ₂ .

Hereinafter, the tractor according to the embodiment of the work vehicle of the present invention will be described in detail with reference to the drawings.

FIG. 1 is an overall left side view of the tractor 1 shown as an example of the work vehicle of the present invention.

FIG. 2 is a schematic perspective view of the tractor 1 of the present embodiment as viewed from the control seat 8 side to the steering wheel 9 side.

FIG. 3 is a perspective view of the tractor 1 of the present embodiment around the elevating / lowering switching lever 14.

As shown in FIG. 1, the tractor 1 of the present embodiment is mounted on the front portion of the traveling vehicle body 2, and the power from the engine 3 arranged in the bonnet is appropriately changed by the power transmission mechanism 100 to output the PTO. It is configured to transmit to the shaft 6 and drive both the pair of left and right front wheels 4L and 4R and the pair of left and right rear wheels 5L and 5R, or only the pair of left and right rear wheels 5L and 5R.

As a result, the operator sitting in the control seat 8 arranged in the cabin 7 provided at the rear of the traveling vehicle body 2 operates the steering wheel 9 to drive while steering the pair of left and right front wheels 4L and 4R.

A work machine 11 such as a rotary cultivator is detachably attached to the lower link 10 projecting rearward from the traveling vehicle body 2, and the work machine 11 is powered by a PTO output shaft 6 projecting rearward from the power transmission mechanism 100. To drive.

Further, a lifting device 12 for raising and lowering the working machine 11 is provided at the rear portion of the traveling vehicle body 2, whose front end side is connected to the working machine lifting cylinder 12a and whose rear end side is connected to the lower link 10.

Further, a left brake pedal 13L and a right brake pedal 13R are provided on the floor at the right foot of the operator in the front lower part of the driver's seat 8 (see FIG. 2), and the pair of left and right rear wheels 5L and 5R are provided. On the other hand, each brake can be applied individually.

Further, on the lower right side of the steering wheel 9, an elevating switching lever 14 for operating the elevating device 12 is arranged so as to be movable substantially in the vertical direction (see arrows A and B in FIG. 3).

That is, when the tractor 1 is stopped or traveling straight, the operator tilts the elevating switching lever 14 in the "raising" direction (see arrow A in FIG. 3) with the fingertip of the right hand to move the elevating switching lever 14 to the root side. When the ON signal from the arranged work machine lift switch 20 is transmitted to the work machine lift control unit 320, the work machine lift control unit 320 receives the ON signal from the work machine lift switch 20 when the vehicle is not turning. Is determined to mean an ascending operation of the elevating device 12, issues a command to the main ascending solenoid 21, operates the work equipment elevating cylinder 12a in the ascending direction of the elevating device 12, and operates to the highest raising position. (See FIG. 7).

Further, contrary to the above, when the tractor 1 is stopped or traveling straight, the operator tilts the elevating switching lever 14 in the "lowering" direction (see arrow B in FIG. 3) with the fingertip of the right hand, thereby causing the elevating switching lever. When the ON signal from the work equipment lowering switch 22 arranged at the base side of 14 is transmitted to the work equipment elevating control unit 320, the work equipment elevating control unit 320 receives the work equipment lowering switch when the vehicle is not turning. The ON signal from 22 is determined to mean a lowering operation of the lifting device 12, and a command is issued to the main lowering solenoid 23 to operate the work equipment lifting cylinder 12a in the lowering direction of the lifting device 12 (FIG. FIG. 7). In this case, the lowering position of the elevating device 12 (that is, the working machine 11) is detected by the elevating lever sensor 24, and the elevating device 12 has reached the lowering position set in advance by the elevating lever (not shown). When is detected, the lowering of the lifting device 12 is stopped by the working machine lowering / stopping command from the working machine raising / lowering control unit 320.

When the tractor 1 starts turning, the elevating device 12 is automatically raised by a command from the work equipment elevating control unit 320.

Further, in the tractor 1 of the present embodiment, while the tractor 1 is turning, the operator tilts the elevating switching lever 14 with the fingertip of the right hand in the "raising" direction (see arrow A in FIG. 3) to switch the elevating and lowering. When the ON signal from the work equipment raising switch 20 arranged at the base side of the lever 14 is transmitted to the work equipment elevating control unit 320, the work equipment elevating control unit 320 means the ascending operation of the elevating device 12. It does not accept it, but accepts it as a command to change the brake pressure of the automatic brake that operates during turning.

That is, in the present embodiment, the lifting / lowering changeover lever 14, the working machine raising switch 20, and the working machine lowering switch 22 have a function of changing the braking pressure of the automatic brake in addition to the function of raising and lowering the lifting device 12. Combined. This point will be described later.

Further, a meter panel 15 is arranged on the front side of the steering wheel 9 (see FIGS. 2 and 4). For example, the state of the engine 3, the elevating state of the working machine 11, the traveling speed of the machine, and the automatic brake described later. Is displayed as an auto brake monitor 15a by turning on the LED lamp while the vehicle is in operation, and the change contents of the initial setting of the automatic brake, which will be described later, are input from the input switch 15c (see FIG. 7) displayed on the touch panel 15b. Can be done.

Further, as shown in FIG. 5, an automatic brake on / off switch 17 for turning on / off the automatic braking function described later and a braking pressure (braking force) are set on the operation panel 16 provided on the right side of the control seat 8. Various switches such as a brake pressure setting dial 18 are arranged for this purpose.

FIG. 4 is a diagram showing a meter panel 15 of the tractor 1 of the present embodiment.

FIG. 5 is a perspective view showing various switches provided on the operation panel 16 of the tractor 1 of the present embodiment.

Next, the power transmission mechanism 100 and the automatic braking mechanism 200 in the tractor 1 of the present embodiment will be described mainly with reference to FIGS. 6 and 7.

FIG. 6 is a schematic view showing a hydraulic circuit in the power transmission mechanism 100 and the automatic braking mechanism 200 in the tractor 1 of the present embodiment.

FIG. 7 is a control block diagram of the tractor 1 of the present embodiment.

The power transmission mechanism 100 of the tractor 1 of the present embodiment has a forward / backward clutch 110 that switches the power from the engine 3 to forward rotation or reverse rotation, and a multi-speed clutch (illustrated) that transfers the driving force switched to forward rotation or reverse rotation. (Omitted), etc., the main transmission unit 120, the auxiliary transmission unit 130 that further shifts the driving force shifted by the main transmission unit 120 in multiple stages, and the left and right rear pair of the driving force shifted by the auxiliary transmission unit 130. The rear wheel differential gear mechanism 140 transmitted to the wheels 5L and 5R and the driving force branched from immediately before the rear wheel differential gear mechanism 140 are transmitted to the front wheels so that the front wheels are driven at the same speed as the rear wheels. The driving force from the 4WD clutch 150 and the 4WD clutch 150, which can be switched to transmit to the front wheels so that the front wheels are driven at a higher speed than the rear wheels, is transmitted to the pair of left and right front wheels 4L and 4R. It is composed of a front wheel differential gear mechanism 160 and the like.

In the 4WD clutch 150, the transmission path is switched so that the front wheels are driven at the same speed as the rear wheels by operating the 4WD solenoid 151 in response to a command from the travel control unit 310, and the travel control unit By operating the front wheel speed-increasing solenoid 152 in response to a command from 310, the transmission path is switched so that the front wheels are driven at a higher speed than the rear wheels (see FIGS. 6 and 7).

Here, before explaining the automatic braking mechanism 200 of the tractor 1 of the present embodiment, the relationship between the pair of left and right brake pedals 13L and 13R and the pair of left and right rear wheel braking devices will be described.

The drive shafts of the rear wheels of the tractor 1 of the present embodiment are provided with a pair of left and right braking devices 210L and 210R (see FIG. 6) capable of individually braking the pair of left and right rear wheels 5L and 5R, respectively. The left brake device 210L and the right brake device 210R, and the above-mentioned left brake pedal 13L and right brake pedal 13R are connected to each other via the left brake cylinder 220L and the right brake cylinder 220R and the linking rod 230, respectively. (See FIG. 6).

As a result, the operator can individually depress the left and right brake pedals 13L and 13R to operate the left and right brake devices 210L and 210R individually and brake the left and right rear wheels 5L and 5R individually. It is a configuration that can be done.

Next, the hydraulic system and the control system of the automatic braking mechanism 200 of the tractor 1 of the present embodiment will be mainly described with reference to FIGS. 6 and 7.

In the hydraulic circuit of the automatic brake mechanism 200 of the present embodiment, as shown in FIG. 6, the hydraulic oil from the pump 240 is supplied to the left brake cylinder 220L and the right brake via the proportional pressure adjusting valve 250, the control valve 260, and the like. It is configured to be supplied to the cylinder 220R and the like.

The set pressure of the hydraulic oil output from the proportional pressure adjusting valve 250 to the control valve 260 side can be set to an arbitrary pressure by a command from the traveling control unit 310 to the proportional pressure adjusting solenoid 251.

For example, when the automatic braking function at the time of turning is activated, the operator initially sets a desired brake pressure using the brake pressure setting dial 18 before starting the work, so that the data of the initial setting value of the brake pressure can be obtained. It is stored in the memory unit 311 provided in the travel control unit 310 via the operation panel 16 (see FIGS. 5 and 7).

Further, in the tractor 1 of the present embodiment, as shown in FIG. 8, the brake pressure P ₀ of the initial set value set in advance by the brake pressure setting dial 18 is set to the “raise” side of the elevating switching lever 14 during turning. It is a configuration that can intermittently increase by ΔP only while continuing the simple operation of defeating.

FIG. 8 is a schematic view showing a change in the brake pressure of the automatic brake in the tractor 1 of the present embodiment.

That is, assuming that the operator initially sets the brake pressure P ₀ using the brake pressure setting dial 18 before starting the work, and also intermittently increases the brake pressure P ₀ during turning. In consideration of the state of the field and the like, the input switch 15c displayed on the touch panel 15b of the meter panel 15 is used, and the increase ΔP of the brake pressure, the time Ton for applying the increase ΔP, and the increase ΔP are not applied. The time pressure can be set arbitrarily (see FIG. 8). The changes (ΔP, Ton, Toff) of the initial setting of the automatic brake input from the input switch 15c are stored in the memory unit 311 provided in the traveling control unit 310 via the meter panel 15 (see FIG. 7). ..

Further, the detection result by the steering angle sensor 270 that detects the steering angles of the pair of left and right front wheels 4L and 4R is transmitted to the traveling control unit 310 (see FIG. 7).

Further, as shown in FIGS. 6 and 7, the control valve 260 is a proportional pressure regulating valve according to a command transmitted from the traveling control unit 310 to the left brake solenoid 261 based on the detection result of (1) the steering angle sensor 270. A left-turning braking circuit that supplies hydraulic oil from 250 to the left brake cylinder 220L and drains the right brake cylinder 220R, and (2) right from the traveling control unit 310 based on the detection results of the steering angle sensor 270. A right-handed turning braking circuit that supplies hydraulic oil from the proportional pressure regulating valve 250 to the right brake cylinder 220R and drains the left brake cylinder 220L by a command transmitted to the brake solenoid 262, and (3) steering angle. If none of the above commands are transmitted from the travel control unit 310 based on the detection result of the sensor 270, the non-braking circuit that does not supply the hydraulic oil from the proportional pressure regulating valve 250 to either the left or right brake cylinders 220L or 220R. It is configured to be switchable to three types of hydraulic circuits.

As a result, in the tractor 1 traveling in the field with the automatic brake on / off switch 17 turned on, for example, when the operator operates the steering wheel 9 to start turning left, the steering angle sensor 270 steers the front wheels 4L. The corner is detected, and the detection result is transmitted to the traveling control unit 310. When the travel control unit 310 determines from the detection result that the tractor 1 is turning left by a predetermined angle or more, it issues a command to the left brake solenoid 261 and the control valve 260 switches to the left turning braking circuit described above.

At the same time, when the travel control unit 310 determines that the tractor 1 is turning to the left by a predetermined angle or more, the travel control unit 310 transmits information to that effect to the work equipment elevating control unit 320, and receives the information to that effect. The machine lift control unit 320 issues a command to the main lift solenoid 21 to operate the work machine lift cylinder 12a to the highest position of the lift device 12.

On the other hand, the set pressure of the hydraulic oil output from the proportional pressure regulating valve 250 to the control valve 260 side is set to the initial set value brake pressure P ₀ stored in the memory unit 311 in advance by the command from the traveling control unit 310. Has been done. Therefore, the hydraulic oil of the brake pressure P ₀ from the proportional pressure regulating valve 250 is supplied to the left brake cylinder 220L, the right brake cylinder 220R is in the drained state, and the left brake device 210L provided on the left rear wheel 5L is initially used. It operates on the braking side at the set brake pressure P ₀ .

Further, even when the operator operates the steering wheel 9 and starts turning to the right, the right braking device 210R provided on the right rear wheel 5R operates on the braking side at the braking pressure P ₀ by the reverse operation of the above. To do.

In this way, when the automatic brake on / off switch 17 is in the "on" state, the automatic braking function is automatically activated when the turning run is started, so the initial setting brake pressure P ₀ is set in advance to weak braking. This makes it possible to make a compact turn while preventing the field scene from becoming rough.

When the travel control unit 310 determines from the detection result of the steering angle sensor 270 that the tractor 1 is turning right or left, it issues a command to the front wheel acceleration solenoid 152, and the front wheels 4L and 4R are the rear wheels. When it is driven at a speed higher than 5L and 5R, and when it is determined from the detection result of the steering angle sensor 270 that the tractor 1 is traveling straight, a command is issued to the 4WD solenoid 151, and the front wheels 4L, 4R and the rear wheels 5L, The configuration is such that the 5R is driven at a constant speed.

Next, a case where the initially set brake pressure P ₀ is intermittently increased by the operation of the operator while the tractor 1 is turning is described.

For example, during a left turn, when the operator determines that the turn is larger than expected, he / she immediately tilts the up / down switching lever 14 to the “raise” side with the fingertip of his / her right hand (FIG. 3). See arrow A).

In this case, since the tractor 1 is turning left, the work equipment elevating control unit 320 that has received the ON signal from the work equipment raising switch 20 does not accept it as meaning the ascending operation of the elevating device 12, and is turning. It receives as a change command of the brake pressure P ₀ of the automatic brake operating during, and transmits the change command to the traveling control unit 310.

If the travel control unit 310 determines that the default brake pressure of the automatic brake exceeds a predetermined weak braking value, the change command is not executed.

Upon receiving the change command, the travel control unit 310 receives the data of the initial setting brake pressure P ₀ stored in advance in the memory unit 311 and the change content of the initial setting stored in advance in the memory unit 311, that is, the increase amount. The calculation unit 312 calculates using the data of ΔP, the time Ton for applying the increase ΔP, and the time Toff for not applying the increase ΔP. Then, as a result of the calculation, the travel control unit 310 applies the changed increased brake pressure P ₁ (= P ₀ + ΔP) for the Ton time, and applies the default brake pressure P ₀ for the Tof time. The data (see FIG. 8) is newly stored in the memory unit 311, and the operator continues the operation of tilting the elevating switching lever 14 to the "raise" side by using the changed data stored in the memory unit 311. Only during this period, a command is issued to the proportional pressure adjusting solenoid 251 so that the increased brake pressure P ₁ and the default brake pressure P ₀ are alternately and repeatedly applied.

As a result, the braking pressure on the left rear wheel 5L increases, and the turning radius of the left turning running becomes smaller.

Then, when the operator determines that the left turn is compact as expected, the operation of tilting the up / down switching lever 14 to the "raise" side is stopped. As a result, the lifting / lowering switching lever 14 immediately and automatically returns to the neutral position, and the ON signal from the working machine raising switch 20 is not transmitted to the working machine raising / lowering control unit 320. Therefore, the traveling control unit 310 uses the memory unit 311. A command is issued to the proportional pressure adjusting solenoid 251 so as to apply the default brake pressure P ₀ stored in.

As a result, when the operator determines that the turning is larger than expected during turning, the operator can immediately perform a simple operation of tilting the up / down switching lever 14 to the "up" side with the fingertip of the right hand. (See arrow A in FIG. 3), the turning radius can be reduced reliably and stably.

In addition, since the brake pressure of the automatic brake can be automatically and intermittently repeatedly changed by a simple lever operation, the operator can use his right foot to correspond to the turning direction of the right brake pedal 13R during turning. Or, the operability can be improved as compared with the operation of repeatedly stepping on the left brake pedal 13L.

Further, since the elevating switching lever 14 also has a function of changing the brake pressure of the automatic brake in addition to the function of raising and lowering the elevating device 12, a dedicated lever or switch for changing the brake pressure of the automatic brake is also provided. There is no need to provide.

When the elevating switching lever 14 is raised or lowered while the tractor 1 is stopped or traveling straight, the work machine up switch 20 and the work machine lowering switch 22 transmit to the work machine elevating control unit 320. To prevent erroneous operation, the ON signal is constant so that the work equipment elevating control unit 320 does not immediately accept the detection of the ON signal, but only when the ON signal continues for a certain period of time or longer. Delay time is set. However, when the elevating switching lever 14 is raised during turning, the delay time is automatically set so that the ON signal from the work equipment elevating switch 20 is immediately received by the work equipment elevating control unit 320. The configuration is set to zero to improve responsiveness.

The traveling vehicle body 2 of the present embodiment corresponds to an example of the traveling vehicle body of the present invention. Further, the pair of left and right brake devices 210L and 210R of the present embodiment correspond to an example of the pair of left and right rear wheel brake devices of the present invention. Further, the pair of left and right brake pedals 13L and 13R of the present embodiment corresponds to an example of the pair of left and right brake pedals of the present invention. Further, the brake pressure setting dial 18 of the present embodiment corresponds to an example of the brake pressure setting switch of the present invention. Further, the traveling control unit 310 and the work equipment elevating control unit 320 of the present embodiment correspond to an example of the control device of the present invention.

Further, the work machine raising switch 20 of the present embodiment corresponds to an example of the brake pressure changing unit of the present invention. Further, the elevating device 12, the working machine elevating cylinder 12a, the main ascending solenoid 21, and the main descending solenoid 23 of the present embodiment are examples of the elevating mechanism of the present invention. Further, the lifting / lowering changeover lever 14, the working machine raising switch 20, and the working machine lowering switch 22 of the present embodiment correspond to an example of the raising / lowering operation switch of the present invention.

In the above embodiment, the configuration in which the brake pressure of the automatic brake can be automatically and intermittently repeatedly changed by a simple lever operation has been described, but the present invention is not limited to this, and for example, the elevating switching lever 14 The brake pressure of the automatic brake may be intermittently increased by the operator manually and repeatedly moving between the "neutral" position and the "raised" position. As a result, even if the braking pressure is insufficient when turning with the automatic brake and the turning radius becomes large, it is easier than the operation of intermittently repeating the work of stepping on the brake pedal on the side corresponding to the turning direction. The brake pressure can be increased and the turning radius can be easily reduced.

Further, in the above embodiment, the lifting / lowering changeover lever 14, the working machine raising switch 20, and the working machine lowering switch 22 have a function of raising and lowering the lifting device 12, as well as a function of changing the brake pressure of the automatic brake. Although the case where the combination is provided has been described, the present invention is not limited to this, and for example, a dedicated switch for changing the braking pressure of the automatic brake may be provided, and an output signal from the dedicated switch may be transmitted to the traveling control unit 310. The dedicated switch having this configuration is an example of the brake pressure changing unit of the present invention.

Further, when a dedicated switch for changing the brake pressure of the automatic brake is provided, if the dedicated switch is set to the "ON" state, the brake pressure may be changed automatically and intermittently. Alternatively, the brake pressure may be changed intermittently by manually repeating the operation of switching between the "on" state and the "off" state of the dedicated switch.

Further, in the above embodiment, the combined switch or the dedicated switch is in the "ON" state in a configuration in which the brake pressure can be automatically and intermittently changed regardless of whether the switch is the combined switch or the dedicated switch. The case where the operator needs to continue to operate the combined switch or the dedicated switch by hand directly or through a lever or the like has been described, but the present invention is not limited to this, and for example, the operator is the dual-purpose switch or the dedicated switch. Once the dedicated switch is operated to the "ON" side, even if you release your hand after that, the "ON" state is maintained, and even if you do not manually operate it to the "OFF" side, it will not be in the "OFF" state. good.

Further, in the above embodiment, the configuration in which the brake pressure of the automatic brake is changed by the operator tilting the elevating switching lever 14 to the “raise” side has been described, but the present invention is not limited to this, for example. A turning angle speed sensor (not shown) that detects the turning angle speed in the yaw direction during turning of the traveling vehicle body 2 and outputs the detection result to the traveling control unit 310 is provided in the vicinity of the handle post 9a (see FIG. 3). The case where 310 determines that the turning angle speed in the yaw direction detected by the turning angle speed sensor is smaller than a predetermined threshold value, and the value set by the brake pressure setting dial 18 is within a predetermined weak braking range. When the determination is made, the travel control unit 310 intermittently increases the default brake pressure of the automatic brake stored in the memory unit 311 during the turning, as shown in FIG. 8, and then the travel control unit 310. but if the turning angular velocity of the detected yaw direction by the turning angular velocity sensor is determined to have exceeded a predetermined threshold value, it may be configured to return the brake pressure of the automatic brake initialization value (see P ₀ in FIG. 8). As a result, when the turning radius becomes too large and the turning angular velocity in the yaw direction becomes slow, the braking pressure of the automatic brake can be automatically and intermittently increased, which is optimal even if the operator does not operate it. Can turn.

Here, the relationship between the turning radius and the turning angular velocity in the yaw direction will be described. When turning using the automatic brake, basically no gear change or accelerator operation is performed during turning. Therefore, it can be assumed that the peripheral speed of the rear wheels on the outer side of the turn without braking is constant, that is, the peripheral speed of the turning locus is constant. Assuming that, a slow turning angular velocity in the yaw direction means that the turning radius is large, and it can be judged that the braking pressure of the rear wheels inside the turning is insufficient. By increasing the default brake pressure of, the turning radius can be adjusted appropriately.

Further, in the above configuration, the function of automatically and intermittently increasing the brake pressure of the automatic brake may be configured so that it can be turned on and off by the operation of the operator. Workers who place importance on the finish of the field surface such as fields may not want the function to operate automatically. In such a case, the function can be turned off for general purpose. Improves sex.

Further, in the above configuration, if the function of automatically and intermittently increasing the brake pressure of the automatic brake is in operation, the auto brake monitor 15a arranged on the meter panel 15 may be blinked at high speed. As a result, the operator can recognize that the function is operating, and the running safety is further improved.

Further, in the above-described embodiment, the configuration in which the vehicle speed during straight-ahead travel is not restricted whether or not the automatic braking is permitted to operate has been described, but the present invention is not limited to this. The traveling control unit 310 may be configured to permit the operation of the automatic brake only when the vehicle speed is equal to or less than a predetermined value (for example, 7 km / h). Further, in the case of this configuration, even if the operation of the automatic brake is permitted, if the vehicle speed exceeds a predetermined value during turning, the operation of the automatic brake is continued as it is. The operation of the function that is changed in the direction of increasing the default brake pressure may not be permitted. As a result, it is possible to prevent high braking from acting when the vehicle speed is faster than a predetermined value, and it is possible to further improve safety.

Further, in the above embodiment, the case where the default brake pressure of the automatic brake is changed intermittently as shown in FIG. 8 has been described, but the present invention is not limited to this, and is shown in FIG. 9A, for example. As described above, the initial setting brake pressure P ₀ of the automatic brake may be continuously increased by ΔP to change the brake pressure to P ₁ . As a result, when the turning radius becomes large, the brake pressure of the rear wheels on the inside of the turning can be continuously increased by a simple operation, and the turning radius can be made an appropriate size. Improves sex. FIG. 9A is a schematic view showing an example of a pressure change having a configuration in which the default brake pressure P ₀ of the automatic brake is continuously increased by ΔP to change the brake pressure to P ₁ .

Further, in the case of this configuration, a dedicated switch is provided, and when the dedicated switch is pressed, the brake pressure continuously increases by the pressure of ΔP (for example, 3 kgf / cm ² ) (see FIG. 9A). Alternatively, as described above, the elevating / lowering switching lever 14 (see FIG. 3) may have a function of elevating and lowering the elevating device 12 as well as a function of changing the brake pressure of the automatic brake. .. As a result, existing levers and switches can be shared, so functions can be added without increasing costs. Further, even in the case of this configuration, as described above, the pressure of ΔP may be set to an arbitrary value. As a result, the optimum value can be set according to the field conditions and the needs of the user, and the versatility is improved.

Further, in the above embodiment, the configuration that can be changed in the direction of increasing the initial setting brake pressure of the automatic brake when the turning radius becomes large has been described, but the present invention is not limited to this, for example, the initial setting of the automatic brake. In addition to the function that can be changed in the direction of increasing the brake pressure of, even if the configuration has a function that can be changed in the direction of decreasing the default brake pressure of the automatic brake (see FIG. 9B). good. FIG. 9B is a schematic view showing an example of a pressure change having a configuration in which the default brake pressure P ₀ of the automatic brake is continuously reduced by ΔP to change the brake pressure to P ₂ . As a result, even if there is a part of the field that you do not want to disturb, or there is a place where you should turn carefully because water is floating, you can easily operate the default brake pressure of the automatic brake. Can be weakened immediately, improving workability. Further, in the case of this configuration, the lifting / lowering changeover lever 14, the working machine raising switch 20, and the working machine lowering switch 22 (see FIGS. 3 and 7) have a function of raising and lowering the lifting device 12, as well as the braking pressure of the automatic brake. It may be configured to also have a function of changing and operating. That is, in the case of this configuration, the travel control unit 310 that determines that the vehicle is turning is based on the detection result of the steering angle sensor 370 (see FIG. 7) in the "raising" direction of the elevating switching lever 14 (FIG. 3). The operation of arrow A) is accepted as meaning the operation of changing the default brake pressure of the automatic brake in the increasing direction, and the operation of the elevating switching lever 14 in the "lowering" direction (see arrow B in FIG. 3). The operation is accepted as meaning an operation of changing the default brake pressure of the automatic brake in the decreasing direction. Further, in the case of this configuration, since the brake pressure is changed by using the elevating switching lever 14, the operator manually operates the elevating switching lever 14 in the "up" direction or the "lowering" direction. The brake pressure is changed by ΔP only while it is in the air, and when the hand is released, the brake pressure returns to the predetermined setting P ₀ .

In addition to the function that can be changed in the direction of increasing the default brake pressure of the automatic brake, this configuration also has the function of being able to change the direction of decreasing the default brake pressure of the automatic brake. However, the present invention is not limited to this, and for example, a configuration having only a function that can be changed in a direction of reducing the default brake pressure of the automatic brake may be used.

Further, in the above embodiment, when the initial setting brake pressure of the automatic brake is changed in the direction of increasing or decreasing, ΔP is changed at once as shown in FIGS. 9A and 9B. However, the present invention is not limited to this, and for example, the pressure may be gradually changed to finally realize the change of ΔP. As a result, a sudden change in pressure can be prevented, and the headland in the field can be prevented from becoming too rough.

Further, as shown in FIGS. 9A and 9B, in the configuration in which the brake pressure is changed by using the elevating switching lever 14, the operator raises the elevating switching lever 14 in the “raising” direction or. The brake pressure is changed by ΔP only while the hand is operated in the “lowering” direction, and the brake pressure returns to the predetermined setting P ₀ when the hand is released. However, the brake pressure is not limited to this, for example. A dedicated switch for performing the change operation, that is, a brake pressure up switch and a brake pressure down switch may be provided. In the case of this configuration, when the operator starts turning and the automatic brake is automatically activated, when the operator turns on the "brake pressure up switch" for the first time, the initial setting of the automatic brake is set. to the brake pressure P _0, a constant specified pressure ΔP is added. Further, after this state, when the operator turns on the "brake pressure down switch", the brake pressure P _{1 to} which a constant specified pressure ΔP is added is the state before the constant specified pressure ΔP is added. Returns to the default brake pressure P ₀ . Further, for example, when the operator starts turning and the automatic brake is automatically activated and the operator turns on the "brake pressure down switch" for the first time, the default brake of the automatic brake is used. A constant specified pressure ΔP is reduced with respect to the pressure P ₀ . After that, when the operator turns on the "brake pressure up switch", the brake pressure P _{2 in} which the constant specified pressure ΔP is reduced is the initial state before the constant specified pressure ΔP is reduced. The brake pressure returns to P ₀ .

Further, in the above embodiment, the operation of changing the brake pressure in the initial setting of the automatic brake is limited to the change within the range of ± ΔP with respect to the initial setting P ₀ no matter how many times the switch is operated. However, the present invention is not limited to this, and for example, the configuration may be changed by ΔP each time the switch is operated. E.g., P when the brake pressure is once operated increase switch for changing the direction of increasing the brake pressure changes from P ₀ to P ₀ + [Delta] P, then when operating the increasing switch again, the brake pressure from P ₀ + [Delta] P _It may be configured to change to ₀ + 2ΔP. Further, in the case of this configuration, when the turning running is completed, the change of the brake pressure is canceled and the default value is returned.

Further, in the above embodiment, the "raising" operation of the elevating switching lever 14 corresponds to the operation of changing the brake pressure of the automatic brake in the direction of increasing, and the "lowering" operation of the elevating switching lever 14 corresponds to the operation of the automatic brake. The case corresponding to the operation of changing the brake pressure in the direction of decreasing the brake pressure has been described, but the present invention is not limited to this, and for example, the "raising" operation of the elevating switching lever 14 may be an operation of changing the brake pressure of the automatic brake in the direction of decreasing the brake pressure. Correspondingly, the "lowering" operation of the elevating switching lever 14 may correspond to the operation of changing the brake pressure of the automatic brake in the direction of increasing the brake pressure.

The work vehicle according to the present invention is useful as a work vehicle because it has an effect that the brake pressure can be easily adjusted even if the brake pressure is insufficient, for example, when turning by the automatic brake.

1 Solenoid 2 Traveling vehicle body 3 Engine 4L, 4R Pair of left and right front wheels 5L, 5R Pair of left and right rear wheels 6 PTO output shaft 11 Work equipment 12 Lifting device 12a Work equipment lifting cylinder 13L, 13R Pair of left and right brake pedals 20 Working machine raising switch 21 Main ascending solenoid 22 Working machine lowering switch 23 Main descending solenoid 24 Elevating lever sensor 100 Power transmission mechanism 210L, 210R A pair of left and right brake devices 220L, 220R A pair of left and right brake cylinders 230 Linked rod 240 Pump 250 Proportional pressure regulating valve 260 Control valve 270 Steering angle sensor 310 Travel control unit 320 Work equipment lift control unit

Claims (3)

With the running body
A pair of left and right rear wheel braking devices that can separately brake the pair of left and right rear wheels provided on the traveling vehicle body,
A pair of left and right brake pedals that operate the pair of left and right rear wheel brake devices,
A brake pressure setting switch that presets the brake pressure applied to the rear wheels on the inside of the turn via the rear wheel brake device corresponding to the rear wheels on the inside of the turn when the traveling vehicle body turns.
When the traveling vehicle body starts the turning, the control device that applies the brake pressure to the rear wheels inside the turning and the control device.
In the middle of the turning, the brake pressure changing unit for changing the preset brake pressure and the brake pressure changing unit
An elevating mechanism that elevates and elevates the work machine connected to the rear of the traveling vehicle body,
An elevating operation switch that operates the elevating mechanism ascending / descending,
With
The control device changes the preset brake pressure in the middle of the turning based on the output from the brake pressure changing unit .
The elevating operation switch also serves as the brake pressure changing unit.
While the traveling vehicle body is making the turn, the control device does not accept the operation command by the elevating operation switch as meaning the ascending / descending operation of the elevating mechanism, and the brake pressure changing unit does not accept the operation command. Accepted as the preset brake pressure change command of the above, and while the traveling vehicle body is not making the turn, the operation command by the elevating operation switch means the ascending / descending operation of the elevating mechanism. Ru accepted as the work vehicle, characterized in that. The work vehicle according to claim 1, wherein the control device intermittently changes the preset brake pressure. The work vehicle according to claim 1, wherein the control device continuously changes the preset brake pressure.