JP6988970B2 - Work vehicle - Google Patents

Description

The present invention relates to a work vehicle.

Conventionally, a work vehicle such as an agricultural tractor decelerates the rotational power output from the engine appropriately through a plurality of gears in a power transmission device and transmits the rotational power to the drive wheels, and by changing the combination of the plurality of gears. Shift gears.

In such a work vehicle, a clutch whose connection pressure can be adjusted is provided in the power transmission device, and the state of shift operation at the time of switching gears is adjusted by changing and adjusting the degree of increase in the connection pressure of the clutch at the time of shifting. Regarding the sensitivity adjustment dial that can be used, the change by the sensitivity adjustment dial is different depending on whether the auxiliary shift is the working speed or the traveling speed, and when the traveling load is small such as when traveling on the road, the shift destination connection pressure is set. The pressure is gradually increased from a low pressure to shift smoothly, and when the traveling load is heavy such as when traveling in the field, the speed change destination connection pressure is rapidly increased so that the power is cut off less. A work vehicle to be adjusted is known (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2016-023715

However, even when the auxiliary shift is switched to the working speed, the running load may be small, and if the shift destination connection pressure is rapidly boosted in such a case, a shock will occur as the clutch is boosted. Was there. That is, even if the above-mentioned conventional techniques are used, the feelings such as starting and shifting (hereinafter, these are collectively referred to as running feelings) may be poor.

The present invention has been made in view of the above, and an object of the present invention is to provide a work vehicle capable of further improving the traveling feeling.

In order to solve the above-mentioned problems and achieve the object, the work vehicle according to claim 1 has a power transmission device (13) for transmitting the rotational power of the engine (4) to the drive wheels (3) and the power. A control unit (100) provided in the transmission device (13) and pre-stores a boosting pattern when the hydraulic clutches (A, B) whose connection pressure can be adjusted and the hydraulic clutches (A, B) are connected. And a booster pattern adjusting switch (76) that is operated when the booster pattern is changed, the control unit (100) has the booster pattern that is operated when the booster pattern adjustment switch (76) is operated. The step-up pattern is changed based on the value of the adjustment switch (76), and the hydraulic clutch includes a forward / backward clutch (A) for switching forward / backward by operating a forward / backward lever (63), and the control unit (100). Is changed by the booster pattern adjustment switch (76) when the forward / backward advance lever (63) is operated to the forward side to start in a state where the booster pattern is changed by the booster pattern adjustment switch (76). has been to connect the forward-reverse clutch (a) in accordance with the step-up pattern after, in a state in which the booster pattern is changed by the step-up pattern control switch (76), the forward-reverse lever (63) is the reverse side when you start to disable the change due to the step-up pattern control switch (76), which is connected to the forward-reverse clutch (a) in accordance with the boosting pattern before being changed by said step-up pattern control switch (76) that Te It is characterized by.

The work vehicle according to claim 2 is the work vehicle according to claim 1, and includes a work machine elevating sensor (140) that connects the work machines so as to be able to move up and down and detects the elevating and lowering of the work machine. 100) invalidates the change by the booster pattern adjustment switch (76) when a certain period of time has elapsed after detecting the rise of the working machine, and when the vehicle is started by operating the forward / backward advance lever (63), the booster pattern to connect the forward-reverse clutch (a) in accordance with the boosting pattern before being changed by the control switch (76) and said Rukoto.

Working vehicle according to claim 3 is the work vehicle according to claim 2, wherein the control unit (100), upon detecting the lowering of the working machine, the boosting pattern by the step-up pattern control switch (76) It is characterized by making changes effective.

According to the first aspect of the present invention, it is possible to suppress the shock at the time of starting in either the high load running or the low load running. Thereby, the running feeling can be further improved.

Further, since high load running (high load work) is rarely performed when moving backward, the shock at the time of starting can be suppressed by disabling the changed boosting pattern when moving backward. Thereby, the running feeling can be further improved.

According to the invention of claim 2, in addition to the effect of the invention of claim 1, it is changed when a certain period of time has passed by raising the working machine, that is, when the work by the working machine is not performed. Since the clutch boost pattern is invalidated, it is possible to prevent a shock from occurring at the time of starting or shifting. Thereby, the running feeling can be further improved.

According to the invention of claim 3, in addition to the effect of the invention of claim 2, the working machine is lowered when the changed clutch boosting pattern is invalidated due to the raising of the working machine. When the work is started or restarted, the clutch boosting pattern is automatically returned to the corrected boosting pattern, so that the work can be started with the clutch boosting pattern suitable for the work content. As a result, the running feeling can be improved and the workability can be improved.

FIG. 1 is a schematic side view of a work vehicle (tractor). FIG. 2 is a transmission diagram in the mission case. FIG. 3 is a schematic plan sectional view of the forward / backward clutch. FIG. 4 is a functional block diagram of the tractor. FIG. 5 is a hydraulic circuit diagram of the tractor. FIG. 6 is a schematic perspective view in front of the cockpit. FIG. 7A is an explanatory diagram (No. 1) of the operation switch. FIG. 7B is an explanatory diagram (No. 2) of the operation switch. FIG. 8 is a schematic perspective view on the right side of the cockpit. FIG. 9A is an explanatory diagram of changing the main shift boosting pattern. FIG. 9B is an explanatory diagram of changing the forward / backward boosting pattern. FIG. 9C is an explanatory diagram of changing the boosting pattern by depressing the clutch pedal. FIG. 10A is a table showing a boost correction amount at the time of shifting with respect to the instruction dial value of the boost pattern adjustment switch. FIG. 10B is a table showing a boost correction amount at the time of starting with respect to the instruction dial value of the boost pattern adjustment switch. FIG. 11A is a diagram (No. 1) showing a display example of the display screen. FIG. 11B is a diagram (No. 2) showing a display example of the display screen.

Hereinafter, embodiments of the work vehicle disclosed in the present application will be described in detail with reference to the accompanying drawings. The present invention is not limited to the embodiments shown below.
<Overall configuration of work vehicle>
FIG. 1 is a schematic plan view of a work vehicle (tractor) 1. FIG. 2 is a transmission diagram in the mission case 12. FIG. 3 is a schematic plan sectional view of the forward / backward clutch A. FIG. 4 is a functional block diagram of the tractor 1. FIG. 5 is a hydraulic circuit diagram of the tractor 1.

In the following, a tractor will be described as an example of the work vehicle 1. The tractor 1 is an agricultural tractor that works in a field or the like while self-propelled. Further, in the following description, the front-rear direction is the traveling direction when the tractor 1 travels straight, and the front side of the traveling direction is defined as "front" and the rear side is defined as "rear". The traveling direction of the tractor 1 is the direction from the driver's seat 8 to the steering wheel 11 when the tractor 1 goes straight (see FIG. 1).

Further, the left-right direction is a direction horizontally orthogonal to the front-back direction. In the following, the left and right are specified toward the "front" side. That is, with the operator (also referred to as the operator) seated in the driver's seat 8 and facing forward, the left hand side is "left" and the right hand side is "right" (see FIG. 6). The vertical direction is the vertical direction. The front-back direction, the left-right direction, and the up-down direction are orthogonal to each other.

As shown in FIG. 1, the tractor 1 includes a front wheel 2, a rear wheel 3, an engine 4 as a drive source, and a transmission 5. The front wheel 2 is mainly provided as a steering wheel, that is, a steering wheel. The rear wheel 3 is mainly provided as a driving wheel, that is, a driving wheel. The rear wheels 3 appropriately decelerate and transmit the rotational power output from the engine 4 mounted in the bonnet 6 on the front 1F of the fuselage by the transmission 5 in the transmission case 12, and generate driving force by the rotational power. do.

The transmission 5 also transmits the rotational power from the engine 4 to the front wheels 2 as needed. In this case, the four wheels of the front wheels 2 and the rear wheels 3 act as driving wheels to generate driving force. That is, the transmission 5 can switch between two-wheel drive and four-wheel drive, decelerates the rotational power of the engine 4, and transmits the decelerated rotational power to the front wheels 2 and the rear wheels 3.

A connecting device 7 to which a working machine (not shown) such as a rotary working machine can be mounted is provided on the rear portion 1R of the tractor 1. The connecting device 7 connects the working machine to the rear portion 1R of the tractor 1 by, for example, left and right lower links or a central top link. For example, the tractor 1 hydraulically rotates the left and right lift arms to raise and lower the work equipment via a lift rod, a lower link connected to the lift rod, and the like.

Further, in the tractor 1, the cockpit 9 is covered around the cockpit 8 on the airframe. In the tractor 1, a steering wheel 11 is provided on a dashboard 10 provided in front of the driver's seat 8 in the cabin 9, and a forward / backward lever 63 and an auxiliary shift lever 75, which will be described later, are provided on the left and right sides and below the driver's seat 8. Various operation levers such as, and various operation pedals such as the clutch pedal 61 and the accelerator pedal 60, which will be described later, are provided.

As shown in FIG. 2, the transmission 5 is arranged in a transmission case 12 (see FIG. 1) and a power transmission mechanism 13 for transmitting rotational power from the engine 4 to the rear wheels 3 and the like. It is composed including and. The power transmission mechanism 13 transmits the rotational power of the engine 4 to the front wheels 2, the rear wheels 3, and the working machine connected to the machine body, and drives the front wheels 2, the rear wheels 3, and the working machine.

The power transmission mechanism 13 includes an input shaft 14, a forward / backward switching device 15, a main transmission 16, a high / low transmission 17, an auxiliary transmission 18, a front wheel transmission 19, and a PTO (Power take-off) drive. It is configured to include the device 20. Of these, the main transmission 16 and the high / low transmission 17 constitute a "main transmission" of the tractor 1, and the auxiliary transmission 18 constitutes a "secondary transmission" of the tractor 1.

The power transmission mechanism 13 transmits the rotational power from the engine 4 to the rear wheels 3 via, for example, an input shaft 14, a forward / reverse switching device 15, a main transmission 16, a high / low transmission 17, and an auxiliary transmission 18. .. Further, the power transmission mechanism 13 transmits the rotational power from the engine 4 through, for example, an input shaft 14, a forward / backward switching device 15, a main transmission 16, a high / low transmission 17, an auxiliary transmission 18, and a front wheel transmission 19. And transmit to the front wheel 2. Further, the power transmission mechanism 13 transmits the rotational power from the engine 4 to the working machine via, for example, the input shaft 14 and the PTO drive device 20 in this order.

The input shaft 14 is provided on the output shaft of the engine 4, and the rotational power from the engine 4 is transmitted (input). In the following, the direction of power transmission is defined as the engine 4 side as the power transmission upstream side, and the final output destinations of the front wheels 2, rear wheels 3 and the working machine side as the power transmission downstream side, respectively. There is.

The forward / backward switching device 15 switches the rotational power transmitted from the engine 4 to forward rotation or reverse rotation. The forward / backward switching device 15 includes a forward hydraulic multi-plate clutch (hereinafter referred to as a forward clutch) A1, a reverse hydraulic multi-plate clutch (hereinafter referred to as a reverse clutch) A2, a forward gear 15a, and a reverse gear 15b. It is equipped with. The forward clutch A1 and the reverse clutch A2 form a "forward / backward clutch A".

The forward / backward clutch A transmits the rotational power transmitted to the input shaft 14 to the main shaft 23 according to the disconnection (connection / disconnection) state of the forward clutch A1 and the reverse clutch A2. In the forward / backward clutch A, when the forward clutch A1 is connected, the forward gear 15a meshes with the forward gear 50a to rotate the main shaft 23 in the normal direction. Further, in the forward / backward clutch A, when the reverse clutch A2 is in the connected state, the reverse gear 15b meshes with the reverse gear 50b to reverse the main shaft 23.

The forward / backward clutch A switches between forward and reverse of the tractor 1 by the forward rotation and the reverse rotation of the main shaft 23. The forward / backward clutch A switches between forward and reverse by hydraulic control, for example, by operating the forward / backward lever 63 in the driver's seat 8 (see FIG. 1). Further, by depressing the clutch pedal 61, both the forward clutch A1 and the reverse clutch A2 are brought into a disengagement state (neutral state).

The main transmission 16 shifts the rotational power from the engine 4 at any of a plurality of shift stages. The main transmission 16 includes a first main speed change clutch B1, a second main speed change clutch B2, a first speed gear 16a, a second speed gear 16b, a third speed gear 16c, and a fourth speed gear 16d as a plurality of shift stages. And have. The first main speed change clutch B1 includes a hydraulic multi-plate clutch (hereinafter referred to as 1st speed clutch) B11 and a hydraulic multi-plate clutch (hereinafter referred to as 3rd speed clutch) B13, and the 1st speed gear 16a is provided on the 1st speed clutch B11 side. Is provided, and a 3rd speed gear 16c is provided on the 3rd speed clutch B13 side.

Further, the second main speed change clutch B2 includes a hydraulic multi-plate clutch (hereinafter referred to as a 2-speed clutch) B22 and a hydraulic multi-plate clutch (hereinafter referred to as a 4-speed clutch) B24, and the 2nd speed gear is on the 2nd speed clutch B22 side. 16b is provided, and a 4-speed gear 16d is provided on the 4-speed clutch B24 side. The first main shift clutch B1 and the second main shift clutch B2 form a "main shift clutch B".

The main speed change clutch B shifts the rotational power from the engine 4 at any of the gear ratios of the 1st speed gear 16a to the 4th speed gear 16d according to the intermittent state of the 1st main speed change clutch B1 and the 2nd main speed change clutch B2. Then, it is transmitted to the latter stage, that is, to the downstream side of the power transmission. In the main shift clutch B, for example, the main shift lever, the main shift speed-up button 121, or the main shift deceleration button 122 (see FIG. 8) is operated in the driver's seat 8, so that the 1st-speed gears 16a to 4th-speed gears are operated. Select one of 16d to shift gears. It should be noted that such a shifting operation can be performed while the tractor 1 is traveling.

The high / low speed changer 17 shifts the rotational power from the engine 4 at a high speed stage or a low speed stage. The high / low transmission 17 includes a Hi (high speed) side hydraulic multi-plate clutch (hereinafter referred to as Hi clutch) C1, a Lo (low speed) side hydraulic multi-plate clutch (hereinafter referred to as Lo clutch) C2, and a Hi (high speed) side gear. It includes a 17a and a Lo (low speed) side gear 17b. The Hi clutch C1 and the Lo clutch C2 form a "Hi-Lo clutch C". The Hi-Lo clutch C changes the transmission path and transmits the rotational power transmitted to the main shaft 23 to the speed change shaft 24 according to the intermittent state of the Hi clutch C1 and the Lo clutch C2.

The Hi-Lo clutch C shifts the rotational power shifted by the main shift clutch B at the gear ratio of the Hi side gear 17a or the gear ratio of the Lo side gear 17b and transmits the rotational power to the rear stage, that is, the power transmission downstream side. In the Hi-Lo clutch C, for example, when the main shift lever, the main shift speed increase button 121, or the main shift deceleration button 122 is operated between the 4th speed and the 5th speed in the driver's seat 8 (see FIG. 1). , It is automatically switched between the Hi side and the Lo side by hydraulic control, and constitutes an 8-speed shift of 4 speeds on the Hi side and 4 speeds on the Lo side. It should be noted that such a shifting operation can be performed while the tractor 1 is traveling.

The auxiliary transmission 18 can shift the rotational power transmitted from the engine 4 via, for example, the forward / backward switching device 15, the main transmission 16, and the high / low transmission 17 in order to any one of a plurality of transmission stages. The auxiliary transmission 18 includes a first auxiliary transmission (first shift shifter) D1 and a second auxiliary transmission (second shift shifter) D2. The first auxiliary transmission D1 and the second auxiliary transmission D2 form an "auxiliary transmission D". The auxiliary transmission D transfers the rotational power transmitted to the transmission shaft 24 to the first auxiliary transmission D1, gears 18a, 18b, gears 18c, 18d, second auxiliary transmission D2, gears 18e, 18f, gears 18g, 18h. The gear is changed and transmitted to the transmission shaft 25 via. The auxiliary transmission D transmits the rotational power transmitted from the engine 4 and shifted by the main transmission 16 or the like to, for example, four-speed shifting to the rear wheel 3 side.

That is, the rotation of the main shaft 23 is shifted by the main shift clutch B that shifts four speeds, the Hi-Lo clutch C that shifts two high and low speeds, and the auxiliary transmission D that mechanically shifts four speeds, and finally. Is transmitted to the transmission shaft 25. In the example shown in FIG. 2, the transmission 5 (power transmission mechanism 13) has 4 speeds, 2 speeds, 4 speeds, and 4 × 2 × 4 = 32, for a total of 32 speeds. It is possible. The 1st to 8th speeds of the main transmission 16 are a speed change gear in which a main speed change clutch B that shifts 4 speeds and a Hi-Lo clutch C that shifts to 2 high and low speeds are combined.

Further, the transmission 5 (power transmission mechanism 13) transmits the rotational power transmitted to the transmission shaft 25 to the rear wheels 3 via the rear wheel differential 26, the axle (drive shaft) 27, the planetary gear mechanism 28, and the like. .. As a result, in the tractor 1, the rear wheels 3 are rotationally driven as drive wheels by the rotational power from the engine 4.

The front wheel transmission 19 transmits the rotational power transmitted to the input shaft 14 to the front wheel 2 side. The front wheel transmission device 19 includes a front wheel speed-increasing clutch E1 and a front wheel constant speed clutch E2. The front wheel speed-increasing clutch E1 and the front wheel constant speed clutch E2 form a "front wheel speed change clutch (4WD clutch) E". The front wheel speed change clutch E is provided on the first front wheel drive shaft 29a, and when the front wheel constant speed clutch E2 is connected, the rotation of the first front wheel drive shaft 29a is transmitted to the second front wheel drive shaft 29b at a constant speed. Further, the front wheel speed change clutch E accelerates the rotation of the first front wheel drive shaft 29a via the gears 19a and 19b and the gears 19c and 19d when the front wheel speed increase clutch E1 is connected to drive the second front wheel. It is transmitted to the shaft 29b.

The front wheel speed change clutch E transmits the rotational power transmitted to the second front wheel drive shaft 29b to the front wheels 2 via the front wheel differential 30, the axle (drive shaft) 31, the vertical shaft 32, the planetary gear mechanism 33, and the like. As a result, the tractor 1 can travel by four-wheel drive of the left and right front wheels 2 and the left and right rear wheels 3.

That is, the rotation of the front wheels 2 transmitted from the shift shaft 25 can be rotated at a higher speed than the rear wheels 3 by the front wheel shift clutch E. Further, the auxiliary transmission D can shift to, for example, 1st speed (ultra-low speed), 2nd speed (low speed), 3rd speed (medium speed), and 4th speed (high speed), but is between the 2nd speed and the 4th speed. As for the speed change, since the synchro mechanism is provided, the speed change can be performed while the tractor 1 is traveling. The auxiliary transmission D may be set to a three-speed transmission specification. Regarding 3-speed specifications, depending on the model, 1st speed (low speed), 2nd speed (medium speed), 3rd speed (high speed) specification, 2nd speed (low speed), 3rd speed (medium speed), 4th speed (high speed) specification The specifications can be changed.

The PTO drive device 20 shifts the rotational power from the engine 4 and outputs the rotational power from the PTO shaft 34 of the rear portion 1R of the machine body (see FIG. 1) to the work machine, thereby driving the work machine by the power from the engine 4. The PTO drive device 20 includes a PTO clutch device 21, a PTO transmission device 22, and a PTO shaft 34. The PTO drive device 20 switches between a drive state for driving the work machine on the rear portion 1R of the machine body and a non-drive state for stopping the drive of the work machine.

The PTO clutch device 21 switches between transmission and disconnection of power to the PTO shaft 34 side. The PTO clutch device 21 includes a PTO hydraulic multi-plate clutch (hereinafter referred to as “PTO clutch”) F and a gear 21a. The gear 21a meshes with a gear 35 provided so as to be rotatable integrally with the input shaft 14. When the PTO clutch F is in the connected state, it is in the PTO drive state in which power is transmitted to the PTO shaft 34 side, and the rotational power transmitted from the input shaft 14 to the gear 21a via the gear 35 is transmitted to the transmission shaft 36. do.

Further, the PTO clutch F is in the PTO non-drive state (neutral state) in which the transmission of the power to the PTO shaft 34 side is cut off by the disconnection state, and the transmission shaft 36 of the rotational power transmitted to the gear 21a is in the neutral state. Block transmission to the side. The PTO clutch F is switched to a PTO drive state or a PTO non-drive state by hydraulic control, for example, by turning on / off the in-vehicle PTO on / off switch or the out-of-vehicle PTO on / off switch by an operator.

The PTO transmission 22 shifts gears when power is transmitted to the PTO shaft 34 side. The PTO transmission 22 includes a first PTO shift clutch (first shift shifter) G1 and a second PTO shift clutch (second shift shifter) G2. When the first PTO speed change clutch G1 is connected to the gear 22a side, the rotation of the transmission shaft 37 is transmitted to the PTO clutch shaft 38 side at a low speed via the gear 37a and the gear 22a. Further, when the first PTO speed change clutch G1 is connected to the gear 22b side, the rotation of the transmission shaft 37 is transmitted to the PTO clutch shaft 38 side via the gear 37b and the gear 22b at a medium speed.

When the second PTO speed change clutch G2 is connected to the gear 22c side, the rotation of the transmission shaft 37 is transmitted to the PTO clutch shaft 38 side at high speed via the gear 37c and the gear 22c. When the second PTO speed change clutch G2 is connected to the gear 22d side, the rotation of the transmission shaft 37 reverses to the PTO clutch shaft 38 side via the gear 39a and the gear 22d provided on the counter shaft 39. Communicate with. The power transmitted to the PTO clutch shaft 38 rotationally drives the PTO shaft 34 via the connecting shaft 40.

Here, with reference to FIG. 3, the structure of the hydraulic clutch will be described by taking the forward / backward clutch A as an example. As described above, the forward / reverse clutch A is a forward / reverse clutch, and the rotational power of the input shaft 14 (see FIG. 2) is rotated forward or reverse and transmitted to the auxiliary transmission shaft (main shaft) 23.

As shown in FIG. 3, the forward / backward clutch A includes a clutch shaft 48a provided on the forward rotation clutch gear (forward gear) 15a. The clutch shaft 48a is rotatably supported by the auxiliary transmission shaft 23 by the bearing 47a and the bearing 47b. A plurality of inner clutch plates 48b are arranged behind the clutch shaft 48a. Further, the rear portion of the clutch shaft 48a is covered with the clutch case 48d, and the presser plate 48e provided inside the front portion of the clutch case 48d is located on the downstream side of the power transmission from the front ends of the plurality of inner clutch plates 48b. Is arranged.

In the clutch case 48d, a plurality of outer clutch plates 48c are alternately arranged so as to be sandwiched between adjacent inner clutch plates 48b. Since the inner clutch plate 48b has a plurality of teeth on the inner side, the inner clutch plate 48b rotates integrally with the clutch shaft 48a. Further, since the outer clutch plate 48c has a plurality of teeth on the outer side, the outer clutch plate 48c rotates integrally with the clutch case 48d.

In the clutch case 48d, a clutch piston 48f urged to the upstream side of power transmission by a spring 48g is provided behind the clutch shaft 48a. A space for a cylinder portion 48h to which hydraulic oil is supplied is formed in the rear portion of the clutch piston 48f. Therefore, in the forward / backward clutch A, hydraulic oil is supplied to the cylinder portion 48h, and when the pressure of the supplied hydraulic oil exceeds the elastic force of the spring 48g, the clutch piston 48f advances, and the inner clutch plate 48b and the outer clutch plate 48c is crimped with the presser plate 48e.

The crimped inner clutch plate 48b and the outer clutch plate 48c come to transmit power to each other by friction, and the rotational power transmitted from the forward rotation clutch gear 15a is transmitted to the clutch case 48d to the clutch case 48d. The sub-shift shaft 23 fitted with the spline rotates.

Further, in a state where hydraulic oil (pressure oil) is not supplied to the cylinder portion 48h and no pressure is applied, the clutch piston 48f retracts due to the elastic force of the spring 48g, so that the inner clutch plate 48b and the outer clutch plate 48c are different from each other. Not crimped. In such a case, since the inner clutch plate 48b and the outer clutch plate 48c do not transmit power to each other, the PTO clutch F (see FIG. 2) is in a state where the power transmission is cut off, and even if the forward rotation clutch gear 15a rotates, the sub The speed change shaft 23 does not rotate.

A reverse rotation clutch gear (reverse gear) 15b is provided on the side opposite to the auxiliary transmission shaft 23 with the clutch case 48d interposed therebetween, and the power on the reverse side is transmitted as in the case of the forward rotation clutch gear 15a described above. (And cut off). Further, also in the Hi-Lo clutch C and the front wheel speed change clutch (4WD clutch) E, those having the same configuration as the above configuration are used. In the PTO clutch F, one having a half structure on one side is used.

As shown in FIG. 4, the control system (control unit) of the tractor 1 controls the rotation of the drive wheels 2 and 3 (see FIG. 2) that control the output of the engine 4 (see FIG. 2) to control the traveling speed. A traveling control unit (also referred to as a traveling system ECU (Electronic Control Unit) or a shift control unit) 100, an engine control unit (also referred to as an engine ECU) 100a for controlling the engine 4, and a working machine elevating to control the elevating and lowering of the working machine. It is equipped with a control unit (also referred to as a work equipment elevating system ECU) 100b. Note that FIG. 4 shows an example in which a rotary working machine is attached to the tractor 1.

The travel control unit 100 has a pressure sensor for measuring the crimping state of each of the clutches A, B (B11, B13, B22, B24), C described above, that is, a first-speed clutch pressure sensor 111, a second-speed clutch pressure sensor 112, and the like. The on / off signals of the 3-speed clutch pressure sensor 113, 4-speed clutch pressure sensor 114, high-speed (Hi) clutch pressure sensor 115, low-speed (Lo) clutch pressure sensor 116, forward clutch pressure sensor 117, and reverse clutch pressure sensor 118 are displayed. Entered.

Further, the traveling control unit 100 detects the operation position from the forward / backward lever operation position sensor 119 and the shift operation by the auxiliary transmission 18 (see FIG. 2) (the shift stage shifted by the auxiliary transmission 18). Each detection signal of the operation position from the sensor (secondary shift lever operation position sensor) 120 is input. Further, each detection signal of the operation position from the main shift speed increase button 121 and the operation position from the main shift deceleration button 122 is input to the travel control unit 100. Further, the traveling control unit 100 is input with a detection signal of the stepping operation position of the clutch pedal 61 (see FIG. 6) from the clutch pedal sensor 123, an instruction dial value of the 4WD switching dial 70, and the like. When the tractor 1 is provided with a main shift lever operation position sensor that detects a shift operation by the main shift lever, the travel control unit 100 receives a detection signal of the operation position from the main shift lever operation position sensor. Entered.

Further, the travel control unit 100 is input with a detection signal of the depression operation position from the accelerator sensor 125 for detecting the depression operation of the accelerator pedal 60 (see FIG. 6) and a travel speed signal from the vehicle speed sensor 126. Further, the traveling control unit 100 has an oil temperature in the mission case 12 (see FIG. 1) from the mission oil oil temperature sensor, an operation position detection signal from the auxiliary shift lever 75 (see FIG. 8), and an accelerator shift setting switch. The setting signal of, the instruction dial value of the boost pattern adjustment switch 76 for setting the clutch pressure (boost pattern or boost curve) described later, and the like are input.

Further, the traveling control unit 100 outputs switching and boosting signals of the forward switching solenoid 127, the forward / backward boosting solenoid 128, the reverse switching solenoid 129, and the clutch pedal solenoid 130 to the forward / backward clutch A. Further, from the traveling control unit 100, from the 1st speed solenoid 131 to the 1st speed clutch B11, from the 3rd speed solenoid 133 to the 3rd speed clutch B13, from the 2nd speed solenoid 132 to the 2nd speed clutch B22, and from the 4th speed solenoid 134 to the 4th speed clutch B24. Switching and boost signals are output, respectively. Further, the traveling control unit 100 outputs switching from the 1st and 3rd speed boosting solenoids 135 and the 2nd and 4th speed boosting solenoids 136 and boosting signals. Further, the traveling control unit 100 outputs the switching from the high-speed (Hi) boost solenoid 137 and the low-speed (Lo) boost solenoid 138 and the boost signal to the high-low (Hi-Lo) clutch C.

An elevating detection signal from the elevating sensor 140 for detecting the elevating of the working machine (rotary working machine) and a lift position signal from the lift arm sensor 141 are input to the working machine elevating control unit 100b. Further, from the work equipment elevating control unit 100b, an ascending signal from the main ascending solenoid 142 and a descending signal from the main descending solenoid 143 are output to the working equipment elevating cylinder (main cylinder) 144.

From the travel control unit 100, the engine control unit 100a, and the work equipment elevating control unit 100b, among the output signals, the travel speed, shift position, engine water temperature, and other data signals are in front of the steering wheel 11 (see FIG. 1). It is displayed on the display unit (meter panel) 150 or the operation panel 151 provided. An operation signal from the input switch 152 is input to the meter panel 150, for example. Further, the traveling control unit 100, the engine control unit 100a, and the work equipment elevating control unit 100b communicate control signals by, for example, CAN (Controller Area Network) communication.

Further, a communication unit 160 is provided between the travel control unit 100, the engine control unit 100a, and the work equipment elevating control unit 100b, and is configured to be able to communicate with a mobile terminal MT such as a tablet PC or a smartphone. The above-mentioned CAN includes not only wired communication but also wireless communication. Further, the mobile terminal MT may have a built-in GPS (MTa). Further, a working machine connector (for example, an AG port) 161 is provided between the working machine elevating control unit 100b and the communication unit 160. This makes it possible to specify the type and model of the working machine connected to the tractor 1.

Further, as shown in FIG. 5, in the tractor 1, the pump P operated by the rotational power of the engine 4 (see FIG. 2) sucks up the lubricating oil in the mission case 2 (see FIG. 2) via a suction filter or the like. Pressure oil is supplied as hydraulic oil in the hydraulic circuit.

As shown in FIG. 5, the tractor 1 is configured to be able to adjust the crimping state of the main shift clutch B (first main shift clutch B1 and second main shift clutch B2), the Hi-Lo clutch C, and the forward / backward clutch A. ing. Such adjustment of the crimping state of each clutch B (B1, B2), C, A is performed by each actuator 201, 202, 203, 204, 205, 206 corresponding to each clutch B (B1, B2), C, A. , 207, 208 are controlled.

In the first main speed change clutch B1, the actuator 201 drives the 1st speed clutch B11 by the hydraulic pressure supplied via the 1st speed solenoid 131, and the actuator 203 drives the 3rd speed clutch by the hydraulic pressure supplied via the 3rd speed solenoid 133. Drive B13. The flow rate of the hydraulic oil supplied to the first main speed change clutch B1 is adjustable by the 1st and 3rd speed step-up solenoid 135 which is a proportional control valve.

In the second main speed change clutch B2, the actuator 202 drives the second speed clutch B22 by the hydraulic pressure supplied via the second speed solenoid 132, and the actuator 204 drives the second speed clutch B22 by the hydraulic pressure supplied via the fourth speed solenoid 134. Drives B24. The flow rate of the hydraulic oil supplied to the first main speed change clutch B1 is adjustable by the 2nd and 4th speed step-up solenoid 136 which is a proportional control valve.

In the Hi-Lo clutch C, the actuator 205 drives the Hi clutch C1 by the hydraulic pressure supplied via the high-speed (Hi) boost solenoid 137, and the actuator 206 drives the hydraulic pressure supplied via the low-speed (Lo) boost solenoid 138. Drives the Lo clutch C2.

In the forward / backward clutch A, the actuator 207 drives the forward clutch A1 by the hydraulic pressure supplied via the forward switching solenoid 127, and the actuator 208 drives the reverse clutch A2 by the hydraulic pressure supplied via the reverse switching solenoid 129. .. The flow rate of the hydraulic oil supplied to the forward clutch A1 and the reverse clutch A2 is adjustable by the forward / backward boost solenoid 128 or the clutch pedal solenoid 130.

Further, each clutch driven by each actuator 201, 203, 202, 204, 205, 206, 207, 208 (first main shift clutch B1, second main shift clutch B2, Hi-Lo clutch C, forward / backward clutch A). ) Is in the crimping state of each pressure provided between each solenoid 131, 133, 132, 134, 137, 138, 127, 129 and each actuator 201, 203, 202, 204, 205, 206, 207, 208. Sensors (1st speed clutch pressure sensor 111, 2nd speed clutch pressure sensor 112, 3rd speed clutch pressure sensor 113, 4th speed clutch pressure sensor 114, high speed clutch pressure sensor 115, low speed clutch pressure sensor 116, forward clutch pressure sensor 117, reverse clutch Each is measured by a pressure sensor 118). Thereby, the crimping of each clutch B (B1, B2), C, A can be adjusted.

Further, in the control unit in the cabin 9, the tractor 1 includes various operation pedals such as the accelerator pedal 60, the clutch pedal 61, and the brake pedal 62, in addition to the steering wheel 11 and the meter panel 150 described above around the driver's seat 8. Various operation levers such as a forward / backward advance lever 63 and an auxiliary shift lever 75 are provided. Further, various operating devices are provided around the driver's seat 8.
<Control section>
Next, various operating devices provided around the cockpit 8 will be described with reference to FIGS. 6, 7A, 7B, and 8. FIG. 6 is a schematic perspective view of the front of the cockpit 8. 7A and 7B are explanatory views of the operation switch. FIG. 8 is a schematic perspective view of the right side of the cockpit 8. The types and arrangements of the operating devices shown in each figure are examples, and are not limited to these.

As shown in FIG. 6, a steering wheel 11 is provided in front of the driver's seat 8. Further, a clutch pedal 61 is provided on the lower left side of the handle post 66 to which the steering wheel 11 is attached, and an accelerator pedal 60 and a brake pedal 62 are provided on the lower right side of the handle post 66. The brake pedal 62 includes left and right brake pedals 62L and 62R.

A forward / backward lever 63 is provided on the upper left side of the handle post 66. A winker lever 67 is provided on the upper right side of the handle post 66. In addition to the winker lever 67, a one-touch elevating lever and the like are provided on the upper right side of the handle post 66. The one-touch lift lever is an operation lever that operates the lift arm for connecting the work equipment so as to move it to the operation position or the uppermost position of the position lever with one touch. Further, the handle post 66 is provided with a PTO shift lever and the like.

Further, as shown in FIG. 6, a dashboard cover 68 is provided in front of the steering wheel 11. The dashboard cover 68 is provided with a meter panel 150 so as to be visible to an operator (operator) seated in the driver's seat 8. The meter panel 150 is provided with a display screen (for example, a liquid crystal monitor) 155, an engine tachometer (tachometer) 156, and the like (see FIGS. 11A and 11B). On the display screen 155, for example, a shift stage display for displaying the currently selected shift stage, a fuel consumption rate display, a traveling speed display, and the like are displayed. Of these, the fuel consumption rate display and the traveling speed display may be displayed so as to be switched at regular time intervals.

Further, for example, the meter panel 150 may be provided with an energy saving monitor lamp. The energy-saving monitor lamp lights up when the fuel-efficient engine output curve is selected with the engine mode selection switch. Further, for example, a traveling / working changeover switch, an engine mode selection switch, and the like are provided on the right side of the dashboard cover 68, for example. When the engine mode selection switch is pressed, the engine 4 (see FIG. 1) is controlled by a fuel-efficient engine output curve.

As shown in FIG. 6, a 4WD selector dial 70 and an input switch 71 are provided on the right side of the handle post 66. As shown in FIG. 7A, the 4WD selector dial 70 is a dial switch that automatically switches to 4WD or 2WD by the 4WD clutch E (see FIG. 2).

By rotating the 4WD switching dial 70, for example, it switches to each running mode of "auto 4WD", "2WD", "4WD", "super full turn", and "2WD turn". When the 4WD switching dial 70 is set to "Auto 4WD", it is normally driven by 2WD, but the vehicle speed is 0.5 km / h under predetermined conditions (for example, when driving on muddy roads, uneven roads, steep slopes, etc., when braking, and when braking. At low speeds below, when the steering wheel 11 is turned to the super full turn position, etc.), it automatically becomes 4WD. If the conditions are not met, the speed automatically returns to 2WD. The "auto 4WD" mode is used, for example, when traveling on a road, entering and exiting a field, loading and unloading a truck, and performing slope work and front loader work.

When the 4WD switching dial 70 is set to "2WD", it is normally driven by 2WD and automatically becomes 4WD during braking. When the 4WD switching dial 70 is set to "4WD", it is normally driven by 4WD. When the 4WD switching dial 70 is set to "super full turn", it is normally driven by 4WD, and when the steering handle 11 (see FIG. 6) is turned, the front wheel 2 turns faster, and it is possible to make a quick turn with a small turn. Become. Further, when the 4WD switching dial 70 is set to "2WD turn", it is normally driven by 4WD, and when the steering handle 11 is turned, the driving of the front wheels 2 is released and only the rear wheels 3 are driven (2WD). , It is possible to make a quick turn with a small turn. The "2WD turn" mode is effective when used when the field is not to be disturbed by the rotation of the front wheel 2.

Further, for example, a one-touch tillage switch 72 (see FIG. 7B) and an input switch may be provided on the right side of the handle post 66. As shown in FIG. 7B, the one-touch tillage switch 72 is a switch that can set the drive state of the tractor 1 and various controls with one touch. The one-touch tillage switch 72 switches to, for example, each mode of "running", "stickiness", and "cultivation". When the one-touch tillage switch 72 is set to "running", the running mode set to any of the above-mentioned "auto 4WD", "4WD", and "2WD" is activated.

When the one-touch tillage switch 72 is set to "tillage", functions convenient for general tillage work such as automatic horizontal, four-wheel drive, and front wheel speed increase ("super full turn" mode) are activated. In addition, if the one-touch tillage switch 72 is set to "stickiness", the operator can set the functions required for tillage.

Further, as shown in FIG. 8, on the right side of the driver's seat 8, there are an auxiliary shift lever 75, a main shift speed increase button 121, a main shift deceleration button 122, a step-up pattern adjustment switch (hereinafter referred to as a shift sensitivity dial) 76, and the like. Is provided. Further, a position lever 77 and an accelerator lever 80 are provided on the right side of the driver's seat 8. The position lever 77 operates the above-mentioned raising and lowering of the lift arm. Further, on the right side of the driver's seat 8, operation switches such as a PTO automatic / manual changeover switch 78, a PTO on / off switch, an engine rotation indicator, a rotation speed increase adjustment switch, and a rotation speed decrease adjustment switch are provided. .. Of the operation switches, the PTO automatic / manual changeover switch 78 automatically disconnects the PTO clutch F (see FIG. 2) when the lift arm rises to a certain height or higher. Further, on the right side of the driver's seat 8, an operation panel storage box 79 for storing an operation panel on which other operation switches and the like are arranged is provided.

Here, the traveling control unit 100 (see FIG. 4) controls the connection pressure (clutch pressure) of the hydraulic clutches such as the forward / backward clutch A and the main shift clutch B (see FIG. 2) to increase the pressure (or increase). (Also called a curve) is set. The travel control unit 100 stores the boosting pattern at the time of connecting the hydraulic clutch in a storage unit or the like in advance.
<Control of boosting pattern when hydraulic clutch is connected>
Next, an example of changing the clutch pressure boosting pattern will be described with reference to FIGS. 9A, 9B, and 9C. FIG. 9A is an explanatory diagram of changing the main shift boosting pattern. FIG. 9B is an explanatory diagram of changing the forward / backward boosting pattern. FIG. 9C is an explanatory diagram of changing the forward / backward step-up pattern by depressing the clutch pedal. In each figure, an example of each boost pattern change is shown as a schematic graph.

In the tractor 1, the traveling control unit 100 (see FIG. 4) controls, for example, a pressure shift pattern in which the clutch pressure of the hydraulic clutch is once lowered and then gradually increased at the time of shifting, thereby suppressing the shifting shock. In this case, the change sensitivity dial 76 (see FIG. 8) is operated (turned) to change the step-up pattern at the time of shifting.

As shown in FIG. 9A, when the main shift boosting pattern is changed, the base pressure Pb, the initial pressure P0 (pressure value at time T0), and the ultimate pressure Pm (pressure value at time Tm) are increased by predetermined ratios, respectively. Further, as shown in FIG. 9B, when the forward / backward boosting pattern (hereinafter referred to as reverse boosting pattern) is changed, the pressure values P0 to P13 corresponding to the times t0 to t13 are increased by predetermined ratios, respectively. Further, as shown in FIG. 9C, when the forward / backward boosting pattern (hereinafter referred to as the clutch boosting pattern) is changed by depressing the clutch pedal 61 (see FIG. 6), the detected value of the clutch pedal sensor 123 (see FIG. 4). That is, the pressure value is increased by a predetermined ratio for each depression operation amount of the clutch pedal 61.

Until now, when changing the reverse boost pattern or the clutch boost pattern, it was necessary to change it, for example, in the check mode of the meter panel 150. For this reason, the operator cannot easily change these boosting patterns when performing high-load work, and a shock may occur at the time of starting or shifting, and the running feeling may deteriorate. Therefore, by operating the shift sensitivity dial 76, the reverse boost pattern and the clutch boost pattern can be arbitrarily changed in addition to the shift boost pattern.

When the shift sensitivity dial 76 is operated, the travel control unit 100 (see FIG. 4) controls to change the reverse boost pattern and the clutch boost pattern according to the operation amount. According to such a configuration, when performing high-load work, the operator can change the boosting pattern at the time of starting or shifting by operating the shift sensitivity dial 76, and the forward / backward lever 63 (FIG. 6). The feeling at the time of starting operation by (see FIG. 6) or at the time of depressing operation of the clutch pedal 61 (see FIG. 6), that is, the running feeling can be further improved.

Note that FIG. 10A is a table showing a boost correction amount at the time of shifting with respect to the instruction dial value of the boost pattern adjustment switch (shift sensitivity dial) 76. As shown in FIG. 10A, the suitable boost correction amount for the instruction dial value of the shift sensitivity dial 76 at the time of shifting is, for example, when the instruction dial value is 0 to 9, the auxiliary shift is other than the speed on the road, that is, "high speed stage". , The auxiliary shift is "0" for both the speed on the road, that is, the "high speed stage". When the instruction dial value is 10 to 512, the auxiliary shift is "1/100 * instruction dial value" except for the "high speed speed", and the auxiliary shift is "1/60 * instruction dial value" when the auxiliary shift is "high speed speed". When the instruction dial value is 513 to 1000, the auxiliary shift is "2/35 * instruction dial value -24" except for "high speed", and the auxiliary shift is "1/60 * instruction dial value" when the auxiliary shift is "high speed". Become. Further, when the instruction dial value is 1001 to 1023, the auxiliary shift is "full pressure" except for the "high speed stage", and the auxiliary shift is "1/60 * instruction dial value" when the auxiliary shift is "high speed stage". When the oil temperature is less than 20 ° C., it is preferable to set the instruction dial value to "0".

Further, FIG. 10B is a table showing a boost correction amount at the time of starting with respect to the instruction dial value of the boost pattern adjustment switch (shift sensitivity dial) 76. As shown in FIG. 10B, the suitable reverse boosting and clutch boosting correction amount for the indicated dial value of the shift sensitivity dial 76 at the time of starting is, for example, when the indicated dial value is 0 to 512, the auxiliary shift is other than "high speed stage". Then, it becomes "1/23 * instruction dial value", and when the auxiliary shift is "high speed", it becomes "0". Further, when the instruction dial value is 513 to 1023, the auxiliary shift is "1/10 * instruction dial value −35" except for the "high speed speed", and the auxiliary shift is "0" when the auxiliary shift is the "high speed speed".

In this case, it is preferable to configure the shift sensitivity dial 76 so as to change the gradients of the reverse step-up curve and the clutch step-up curve when the speed change sensitivity dial 76 is operated by a predetermined dial value or more. According to such a configuration, the situation where the reverse boost pattern or the clutch boost pattern is desired to be changed is during high load work. Therefore, for example, when the shift sensitivity correction is a certain value or more, the gradient of the connection pressure with respect to the instruction dial value is set. By increasing the size, it is possible to realize a running feeling suitable for high-load work.

Here, when the pressure of the reverse step-up pattern or the clutch step-up pattern is increased and the sub-transmission device 18 travels in the "high-speed stage", a large shock may occur. Therefore, in the traveling control unit 100, the auxiliary transmission lever 18 is shifted to the "high speed stage" by the auxiliary transmission lever operation position sensor 120 (see FIG. 4) that detects the operation position of the auxiliary transmission lever 75 (see FIG. 8). When it is detected, the control is performed to temporarily invalidate the boost pattern changed by the shift sensitivity dial 76.

According to such a configuration, when the auxiliary transmission 18 is operated to shift to the "high speed stage", it is assumed that the vehicle is traveling on a road or the like with a low load. If the boost pattern is changed to the expected one, a shock may occur when starting or shifting, so by disabling the changed boost pattern, a shock will occur when starting or shifting. Can be prevented. Thereby, the running feeling can be further improved.

That is, the travel control unit 100 stores in advance a reverse boosting pattern at the time of starting when the forward / backward advance lever 63 is operated to the forward side in a storage unit or the like. When the traveling control unit 100 detects that the auxiliary transmission lever 18 has been shifted to the "high speed stage" by the auxiliary transmission lever operation position sensor 120 that detects the operation position of the auxiliary transmission lever 75, the shift sensitivity Control is performed to temporarily invalidate the reverse boost pattern changed by the dial 76.

According to such a configuration, it is possible to suppress a shock at the time of starting regardless of whether the vehicle is traveling with a high load or a low load. Thereby, the running feeling can be further improved. In addition, since it rarely runs under high load (work with high load) when moving backward, it is possible to suppress the shock at the time of starting by temporarily disabling the changed reverse boost pattern when moving backward. can. Thereby, the running feeling can be further improved.

Further, the traveling control unit 100 stores in advance a clutch boosting pattern when the forward / backward clutch A is connected when the clutch pedal 61 is depressed. When the traveling control unit 100 detects that the auxiliary transmission lever 18 has been shifted to the "high speed stage" by the auxiliary transmission lever operation position sensor 120 that detects the operation position of the auxiliary transmission lever 75, the shift sensitivity Control is performed to temporarily invalidate the clutch boost pattern changed by the dial 76.

According to such a configuration, it is possible to suppress a shock (shock at the time of starting) when the forward / backward clutch A is connected by the operation of depressing the clutch pedal 61. Thereby, the running feeling can be further improved.

Further, the traveling control unit 100 stores in advance the main shift boosting pattern of the shift destination at the time of shifting by the main shift clutch B in a storage unit or the like. When the traveling control unit 100 detects that the auxiliary transmission lever 18 has been shifted to the "high speed stage" by the auxiliary transmission lever operation position sensor 120 that detects the operation position of the auxiliary transmission lever 75, the shift sensitivity Control is performed to temporarily invalidate the main shift boosting pattern changed by the dial 76.

According to such a configuration, it is possible to suppress a shock at the time of connecting the main shift clutch B, that is, a so-called shift shock, regardless of whether the traveling is a high load or a low load. Thereby, the running feeling can be further improved.

Further, when the auxiliary transmission 18 is changed to "medium speed" and "on" is selected by the AT shift which can switch the road speed or the working speed on / off, the traveling control unit 100 is selected. Control is performed to temporarily invalidate the reverse boost pattern and the clutch boost pattern changed by the shift sensitivity dial 76. According to such a configuration, if the boost pattern is changed to assume high load driving, a shock may occur at the time of starting or shifting. Therefore, the changed reverse boost pattern or clutch boost pattern By disabling, it is possible to prevent a shock from occurring when starting or shifting. As a result, the driving feeling can be improved and the safety can be improved.

Further, the traveling control unit 100 changes the reverse speed by the shift sensitivity dial 76 when the auxiliary transmission 18 is changed to "medium speed" and the main transmission 16 is changed to "4th speed" or higher. Controls to temporarily disable the boost pattern and clutch boost pattern. According to such a configuration, if the boost pattern is changed to assume high load driving, a shock may occur at the time of starting or shifting. Therefore, the changed reverse boost pattern or clutch boost pattern By disabling, it is possible to prevent a shock from occurring when starting or shifting. As a result, the driving feeling can be improved and the safety can be improved.

Further, the traveling control unit 100 has a reverse boost pattern or clutch changed by the shift sensitivity dial 76 when the "auto 4WD" or "2WD" mode (see FIG. 7A) by the 4WD switching dial 70 described above is selected. Controls to temporarily disable the boost pattern. According to such a configuration, if the boost pattern is changed to assume high load driving, a shock may occur at the time of starting or shifting. Therefore, the changed reverse boost pattern or clutch boost pattern By disabling, it is possible to prevent a shock from occurring when starting or shifting. As a result, the driving feeling can be improved and the safety can be improved.

Further, when the "traveling" mode (see FIG. 7B) by the one-touch tillage switch 72 described above is selected, the traveling control unit 100 temporarily sets the reverse boosting pattern or the clutch boosting pattern changed by the shift sensitivity dial 76. Control to disable. According to such a configuration, if the boost pattern is changed to assume high load driving, a shock may occur at the time of starting or shifting. Therefore, the changed reverse boost pattern or clutch boost pattern By disabling, it is possible to prevent a shock from occurring when starting or shifting. As a result, the driving feeling can be improved and the safety can be improved.

Further, the traveling control unit 100 has a reverse boosting pattern or a clutch boosting pattern changed by the shift sensitivity dial 76 when a certain period of time has elapsed after the work equipment elevating sensor 140 (see FIG. 4) detects the elevation of the work equipment. Is controlled to be temporarily disabled. According to such a configuration, the reverse boost pattern or the clutch boost pattern changed when the work machine is raised and a certain period of time has passed (that is, the work machine is not working) is invalidated to start the vehicle. It is possible to prevent a shock from occurring at the time of shifting or shifting. As a result, the running feeling can be improved and the workability can be improved.

In this case, the travel control unit 100 may control the pressure of the reverse boost pattern or the clutch boost pattern changed by the shift sensitivity dial 76 so as to gradually decrease with the passage of time without invalidating the pressure at once. With such a configuration, when the work machine is raised and a certain period of time has passed (that is, the work machine is not working), the pressure of the changed reverse step-up pattern or clutch step-up pattern is reduced to reduce the pressure at the time of starting. It is possible to prevent a shock from being generated at the time of shifting. As a result, the running feeling can be improved and the workability can be improved.

Further, the traveling control unit 100 determines the reverse boosting pattern and the clutch boosting pattern changed by the shift sensitivity dial 76 when a certain period of time has elapsed after the rising of the working machine is detected by the working machine elevating sensor 140 as described above. Control to return the reverse boost pattern or clutch boost pattern to the boost pattern corrected according to the instruction dial value of the shift sensitivity dial 76 when the work equipment is lowered when the control is disabled or gradually reduced. I do.

According to such a configuration, when the work machine is lowered to start (restart) the work, the reverse boost pattern and the clutch boost pattern are automatically returned to the corrected boost pattern, so that the reverse boost suitable for the work content is performed. You can start working with a pattern or clutch boost pattern. As a result, the running feeling can be improved and the workability can be improved.

Further, when the traveling control unit 100 detects that the linear shift is "reverse" (automatic ascent of the working machine) and the auxiliary transmission 18 is shifted to "low speed" or "ultra-low speed", the shift sensitivity Control is performed to temporarily invalidate the reverse boost pattern and the clutch boost pattern changed by the dial 76.

According to such a configuration, for example, when the tractor 1 is parked or the work equipment is removed, the reverse boost pattern changed by the shift sensitivity dial 76 and the shock at the time of starting due to the clutch boost pattern are suppressed. Can be done. As a result, the driving feeling can be improved and the safety can be improved.

11A and 11B are views showing a display example of the display screen 115. As described above, the travel control unit 100 may control the shift sensitivity dial 76 so as to change the gradients of the reverse boost curve and the clutch boost curve when the shift sensitivity dial 76 is operated by a predetermined indicator dial value or more. When the instruction dial value according to 76 is larger than the predetermined instruction dial value, a warning may be displayed to the operator to pay attention to the shock at the time of starting. For example, as shown in FIG. 11A, the travel control unit 100 controls to display a warning message on the display screen 155 of the meter panel 150. When the pressure of the reverse boost pattern or the clutch boost pattern is increasing, a large shock (start shock) may occur when starting with a low load, so a warning can be used to avoid danger. That is, safety can be improved.

Further, as described above, the traveling control unit 100 may control to change the gradients of the reverse booster curve and the clutch booster curve when the shift sensitivity dial 76 is operated by a predetermined instruction dial value or more. When the auxiliary transmission 18 is changed to the "high speed stage" in a state where the instruction dial value by the sensitivity dial 76 is larger than the predetermined instruction dial value, a warning may be displayed on the meter panel 150, for example. Further, the travel control unit 100 may be configured to emit a warning sound such as a buzzer together with the warning display. Since it is dangerous to drive on the road (secondary shift "high speed") when the pressure of the reverse boost pattern or the clutch boost pattern is increasing, it is possible to avoid the danger by giving a warning. That is, safety can be improved.

Further, the traveling control unit 100 controls to change the reverse boosting pattern and the clutch boosting pattern by the shift sensitivity dial 76. In this case, the pressure gradient of the reverse boosting pattern and the clutch boosting pattern with respect to the instruction dial value of the shifting sensitivity dial 76. May be switched for each shift stage of the auxiliary transmission 18 (for example, "ultra-low speed stage", "low speed stage", "medium speed stage", "high speed stage"). For example, even if the work content is the same, the load may change depending on the vehicle speed range. Therefore, by switching the pressure gradient of the reverse boost pattern or the clutch boost pattern for each shift stage of the auxiliary transmission 18 as described above, each work content The optimum boost pattern can be obtained. This makes it possible to improve workability.

Further, for example, as shown in FIG. 11B, in the meter panel 150, the pressure change amount with respect to the dial value of the reverse boost pattern or the clutch boost pattern changed by the shift sensitivity dial 76 can be input from the meter panel 150 or, for example. It may be configured so that it can be changed by an input operation from another input unit. Further, the pressure change amount of the reverse boost pattern or the clutch boost pattern may be configured to be changeable by, for example, an input operation from the mobile terminal MT (see FIG. 4). By making it possible to easily change the reverse boost pattern and the clutch boost pattern in this way, it is possible to easily handle a wide range of work from low load to high load. This makes it possible to improve workability.

Further, for example, when a working machine compatible with the AG port, which is a communication standard for agricultural machinery, is attached to the tractor 1, the tractor 1 is connected to the working machine connector (AG port) 161 (see FIG. 4), for example. On the display screen 155 of the meter panel 150 (see FIGS. 11A and 11B), the dial value of the shift sensitivity dial 76, which is the reverse boost pattern or the clutch boost pattern corresponding to the mounted work machine, is notified (displayed). You may do it. In this case, for example, in a graphic display or the like, if the shift sensitivity dial 76 is deviated to the left or right from an appropriate dial value depending on the work machine, it may be instructed to be in an appropriate position. As an example, for example, when the shift sensitivity dial 76 is shifted to the left, an instruction is given to turn it to the right. Although the work load differs depending on the work machine, it is possible to set an appropriate reverse step-up pattern and clutch step-up pattern according to the work machine by adopting such a configuration. As a result, the running feeling can be improved and the workability can be improved.

Further, when a work machine compatible with the AG port is attached to the tractor 1, for example, the dial value of the shift sensitivity dial 76 is within a predetermined specified range by being connected to the work machine connector 161 (AG port). In this case, the reverse boosting pattern or the clutch boosting pattern may be changed so that the boosting pattern is determined for each type of working machine, for example. According to such a configuration, the work efficiency and the work environment can be improved by automatically correcting the step-up pattern determined for each work machine.

Further effects and variations can be easily derived by those skilled in the art. For this reason, the broader aspects of the invention are not limited to the particular details and representative embodiments described and described above. Thus, various modifications can be made without departing from the spirit or scope of the overall concept of the invention as defined by the appended claims and their equivalents.

1 Work vehicle (tractor)
2 Front wheels 3 Rear wheels 4 Engine 5 Transmission
12 Mission case 13 Power transmission mechanism 15 Forward / backward switching device 16 Main transmission device 17 High / low transmission device 18 Secondary transmission device 19 Front wheel transmission device 20 PTO drive device 21 PTO clutch device 22 PTO transmission device 60 Accelerator pedal 61 Clutch pedal 62 Brake pedal 63 Forward / backward lever 70 4WD changeover dial 72 One-touch tillage switch 75 Auxiliary shift lever 76 Boost pattern adjustment switch (shift sensitivity dial)
77 Position lever 100 Control unit (travel control unit)
100a Engine control unit 100b Work equipment lift control unit 119 Forward / backward lever operation position sensor 120 Sub transmission sensor (sub transmission lever operation position sensor)
150 Display (meter panel)
155 Display screen (LCD monitor)
160 Communication unit 161 Connector for work equipment (AG port)
A Forward / backward clutch B Main shift clutch B1 1st main shift clutch B2 2nd main shift clutch C Hi-Lo clutch C1 Hi side hydraulic multi-plate clutch (Hi clutch)
C2 Lo side hydraulic multi-plate clutch (Lo clutch)
D Sub-transmission D1 1st sub-transmission D2 2nd sub-transmission E Front wheel speed change clutch E1 Front wheel speed-increasing clutch E2 Front wheel constant speed clutch F PTO clutch G1 1st PTO speed change clutch G2 2nd PTO speed change clutch MT mobile terminal

Claims (3)

A power transmission device that transmits the rotational power of the engine to the drive wheels,
A hydraulic clutch provided in the power transmission device and the connection pressure can be adjusted,
A control unit that stores the boosting pattern when the hydraulic clutch is connected in advance, and
It is equipped with a booster pattern adjustment switch that is operated when increasing the pressure value of the booster pattern.
The control unit
When the boost pattern adjustment switch is operated, the boost pattern is changed based on the value of the boost pattern adjustment switch.
The hydraulic clutch is
Includes a forward / backward clutch that switches forward / backward by operating the forward / backward lever.
The control unit
When the forward / backward lever is operated to the forward side to start in a state where the boost pattern is changed by the boost pattern adjustment switch, the forward / backward clutch is according to the boost pattern after being changed by the boost pattern adjustment switch. To connect ,
In a state where the boosted pattern by the step-up pattern control switch is changed, when the forward-reverse lever starts to move is operated to the reverse side, to disable the change due to the step-up pattern control switch, by the step-up pattern control switch working vehicle according to claim Rukoto to connect the forward-reverse clutch in accordance with the step-up pattern before being changed. Work equipment can be connected up and down freely,
Equipped with a work equipment elevating sensor that detects the elevating of the work equipment
The control unit invalidates the change by the step-up pattern adjustment switch when a certain period of time has elapsed after detecting the rise of the working machine, and is changed by the step-up pattern adjustment switch when the vehicle is started by operating the forward / backward lever. working vehicle according to claim 1, characterized in Rukoto to connect the forward-reverse clutch in accordance with the step-up pattern of before. Working vehicle according to claim 2 wherein the control unit, which upon detecting the lowering of the working machine, characterized in that the changes to take effect of the boosting pattern by the step-up pattern control switch.

Images