JP2009287470A - Engine speed setting structure of working vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To change the setting of an engine speed stored in a storage means, while simplifying an operation structure. <P>SOLUTION: An engine speed control structure of a working vehicle has artificially operable command means 37 and 38 for commanding reading-out of the engine speed stored in the storage means 21D, and a control means 36 for performing constant rotation control for controlling an output rotating speed so that the engine speed stored in the storage means 21D is provided as an output rotating seed of an engine 1 based on operation of the command means 37 and 38, and is constituted so that the control means 36 performs storage rotating speed changing control capable of changing the setting of the engine speed stored in the storage means 21D based on its another operation when performing the another operation different from the operation for the commanding means 37 and 38. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention provides an artificially operated command means for instructing reading of the engine speed stored in the storage means, and the engine speed stored in the storage means as the engine output speed based on the operation of the command means. The present invention relates to an engine rotational speed control structure for a work vehicle, comprising control means for executing constant rotational control for controlling the output rotational speed as obtained.

As an engine speed control structure for a work vehicle as described above, there is one equipped with a preset accelerator setting device that enables a setting change of the engine speed stored in the storage means (see, for example, Patent Document 1).
JP-A-1-195933

  According to said structure, based on the output of a preset accelerator setting device, a control means performs the memory | storage rotation speed change control which enables the setting change of the engine speed memorize | stored in the memory | storage means.

  In other words, the conventional configuration includes a command unit that commands the control unit to change the setting of the engine speed stored in the storage unit, in addition to the command unit that commands reading of the engine speed stored in the storage unit. There was room for improvement in the simplification of the operation structure.

  An object of the present invention is to make it possible to change the setting of the engine speed stored in the storage means while simplifying the operation structure.

In order to achieve the above object, in the invention according to claim 1 of the present invention,
An artificially operated command means for instructing reading of the engine speed stored in the storage means, and the engine speed stored in the storage means can be obtained as the engine output speed based on the operation of the command means. An engine rotation speed control structure for a work vehicle, comprising a control means for performing constant rotation control for controlling the output rotation speed,
When the control means performs another operation different from the operation, the control means enables the control means to change the setting of the engine speed stored in the storage means based on the other operation. It is comprised so that may be performed.

  According to this characteristic configuration, the command means has a function of instructing the control means to execute the constant rotation control and a function of instructing the control means to execute the stored rotation speed change control.

  Further, since the command means has two related functions, the operation becomes easy.

  Therefore, it is possible to change the setting of the engine speed stored in the storage means while simplifying the operation structure and improving the operability.

In the invention according to claim 2 of the present invention, in the invention according to claim 1,
In the stored rotational speed change control, the control means is configured to change the engine rotational speed stored in the storage means based on an operation of the command means.

  According to this characteristic configuration, the command means stores the function for instructing the control means to execute the constant rotation control, the function for instructing the control means to execute the stored rotation speed change control, and the storage means in the memory rotation speed change control. And a function as an operating tool for changing the engine speed.

  Further, since the command means has three related functions, the operation is further facilitated.

  Therefore, the engine speed stored in the storage means can be changed while further simplifying the operation structure and improving the operability.

In the invention according to claim 3 of the present invention, in the invention according to claim 2,
The command means is composed of two momentary switches,
The storage means stores an engine speed corresponding to one momentary switch and an engine speed corresponding to the other momentary switch,
The operation is a short press operation within a set time of the momentary switch, and the other operation is a long press operation exceeding the set time of the momentary switch,
The control means is
Based on the short-pressing operation of the one momentary switch, the first constant rotation control for controlling the output rotation speed so that the engine rotation speed corresponding to the one momentary switch is obtained as the output rotation speed of the engine. Run as constant rotation control,
A second constant rotation control for controlling the output rotational speed so that an engine rotational speed corresponding to the other momentary switch is obtained as an output rotational speed of the engine based on the short pressing operation of the other momentary switch; Run as constant rotation control,
Based on the long-pressing operation of the one momentary switch, the first stored rotation speed change control that enables the setting change of the engine rotation speed corresponding to the one momentary switch stored in the storage means is stored in the stored rotation speed Run as change control,
Based on the long-pressing operation of the other momentary switch, the second stored rotation speed change control for enabling the setting change of the engine speed corresponding to the other momentary switch stored in the storage means is stored in the stored rotation speed. Run as change control,
In both the first stored rotational speed change control and the second stored rotational speed change control, the engine rotational speed to be controlled at that time is changed in a direction of increasing based on the operation of the one momentary switch. , And the other momentary switch is configured to change in a decreasing direction based on the operation of the momentary switch.

  According to this characteristic configuration, by operating one momentary switch, a constant speed state (hereinafter referred to as the first storage rotational speed) corresponding to the engine rotational speed (hereinafter referred to as the first storage rotational speed) corresponding to the one momentary switch stored in the storage means. The vehicle body can be driven in a single memory constant speed state).

  Further, by operating the other momentary switch, a constant speed state (hereinafter referred to as a second stored constant speed) by an engine speed (hereinafter referred to as a second stored speed) corresponding to the other momentary switch stored in the storage means. The vehicle body can be made to travel.

  That is, two types of constant speed states, the first stored constant speed state and the second stored constant speed state, can be obtained. Therefore, for example, if the first memory constant speed state is for plowing work and the second memory constant speed state is for plowing work, each momentary switch between the constant speed state for plowing work and the constant speed state for plowing work Can be easily obtained by the operation. Further, if the first memory constant speed state is for work and the second memory constant speed state is for headland turning, the operation of each momentary switch is performed between the constant speed state for working and the constant speed state for headland turning. Can be easily obtained.

  In addition, one momentary switch has a function for instructing the control means to execute the first constant rotation control, a function for instructing the control means to execute the first stored rotation speed change control, and a first stored rotation speed change control or It has a function as an operating tool for changing the engine rotational speed stored in the storage means in the second storage rotational speed change control in the increasing direction. The other momentary switch has a function for instructing the control means to execute the second constant rotation control, a function for instructing the control means to execute the second stored rotation speed change control, and the first stored rotation speed change control or It has a function as an operating tool for changing the engine rotational speed stored in the storage means in the second storage rotational speed change control so as to decrease it.

  That is, it is possible to provide a dedicated operating tool for changing the engine speed stored in the storage means in the increasing direction and a dedicated operating tool for changing in the decreasing direction without providing a dedicated operating tool. Thereby, for example, the first stored rotational speed is changed to a direction of increasing by a short press operation of one momentary switch and changed to a direction of decreasing by a long press operation, and the second stored rotational speed is changed to The setting of the first stored rotational speed and the second stored rotational speed is changed as compared with the case of changing to the direction of increasing by a short press operation of the other momentary switch and changing to the direction of decreasing by a long press operation. It becomes easy.

  Therefore, the operation structure can be simplified and the operability can be improved while enabling switching between the first stored constant speed state and the second stored constant speed state according to the work to be performed.

In the invention according to claim 4 of the present invention, in the invention according to claim 3,
In any of the first stored rotational speed change control and the second stored rotational speed change control, the control means is
When the short pressing operation of the one momentary switch is performed, the engine speed to be controlled at that time is changed in a direction to increase by a predetermined speed,
When the short-pressing operation of the other momentary switch is performed, the engine speed to be controlled at that time is changed in a direction to decrease by a predetermined speed,
When the long-pressing operation of the one momentary switch is performed, while the operation is continued, the engine rotational speed to be controlled at that time is changed to a continuously increasing direction,
When the long-pressing operation of the other momentary switch is performed, the engine rotational speed to be controlled at that time is continuously changed so as to continuously decrease while the operation is continued. It is characterized by that.

  According to this characteristic configuration, the operation method of each momentary switch can be properly used depending on whether the engine speed stored in the storage means is changed to a small value or to a large value.

  Therefore, it is possible to improve the operability when changing the engine speed stored in the storage means.

  Hereinafter, as an example of the best mode for carrying out the present invention, an embodiment in which the engine speed setting structure of a work vehicle according to the present invention is applied to a tractor as an example of the work vehicle will be described with reference to the drawings.

  FIG. 1 is an overall side view of the tractor. This tractor has an engine 1 mounted on the front thereof. The rotational power output by the engine 1 is transmitted to the rear pair of left and right front wheels 3 via a clutch (not shown) that interrupts the rotational power, a transmission (not shown) built in a transmission case 2 that also serves as a frame, and the like. The power is transmitted to the wheel 4 and the power take-off shaft 5 projecting rearward from the rear part of the transmission case 2. At the rear of the tractor, a steering wheel 6 for steering the front wheels, a driver's seat 7 and the like are provided to form a boarding operation unit 8, and a cabin 9 that covers the boarding operation unit 8 is equipped.

  As shown in FIG. 2, the engine 1 includes a common rail fuel injection device 10 that electronically controls the fuel injection amount and injection timing. The fuel injection device 10 includes a supply pump 12 that pumps fuel stored in a fuel tank 11, a common rail 13 that accumulates the pumped fuel, a plurality of injectors 14 that injects the accumulated fuel into a fuel chamber (not shown), and a common rail 13. A pressure sensor 15 for detecting the internal pressure of the engine, and an engine control unit (hereinafter abbreviated as ECU) 16 for controlling the operation of the supply pump 12 and each injector 14 based on the output of the pressure sensor 15 and the like. It is configured.

  As shown in FIG. 1, a pair of left and right lift arms 17, a link mechanism 18 for connecting a working device, and a pair of left and right lifts that swing the left and right lift arms 17 in the vertical direction are disposed at the rear of the transmission case 2. The cylinder 19 is equipped. As a result, various working devices (not shown) such as a rotary tiller and a plow can be installed so that they can be raised or lowered, or can be raised and lowered, depending on the work contents.

  The left and right lift cylinders 19 are single acting hydraulic cylinders. The left and right lift cylinders 19 extend and contract when the flow of hydraulic oil to them is controlled by the operation of the electromagnetic control valve 20.

  As shown in FIG. 2, the tractor is equipped with a control device 21 composed of a microcomputer. The control device 21 is provided with a lifting control means 21A for controlling the lifting and lowering of the working device as a control program.

  The raising / lowering control means 21A is configured to execute position control for positioning the working device at an arbitrary height position, forced raising control for forcibly raising the working device to the upper limit position, and the like.

  In the position control, the output of the first lever sensor 23 that detects the operation position of the first elevating lever 22, the output of the lift arm sensor 24 that detects the vertical swing angle of the lift arm 17, and the outputs are associated with each other. Based on the map data for raising and lowering, the output of the lift arm sensor 24 corresponds to the output of the first lever sensor 23 (contains within the dead band width of the output of the first lever sensor 23). The left and right lift cylinders 19 are expanded and contracted by controlling the operation.

  The forcible ascent control is executed in preference to the other elevating control when the second lever sensor 26 that detects the operation of the second elevating lever 25 detects an operation from the neutral position of the second elevating lever 25 to the upper side. To do. In the forced ascent control, based on the output of the lift arm sensor 24 and the preset upper / lower limit value, the output of the lift arm sensor 24 corresponds to the upper / lower limit value (contains within the dead zone width of the upper limit / lower limit value) The operation of the electromagnetic control valve 20 is controlled to extend the left and right lift cylinders 19. When the second lever sensor 26 detects an operation from the neutral position of the second elevating lever 25 to the lower side after the forced ascent, the output of the first lever sensor 23, the output of the lift arm sensor 24, the map data for elevating, Based on the control, the operation of the electromagnetic control valve 20 is controlled so that the output of the lift arm sensor 24 corresponds to the output of the first lever sensor 23 (contains within the dead band width of the output of the first lever sensor 23). The lift cylinder 19 is contracted, and then the forced increase control is terminated.

  The map data for ascending / descending corresponds to the outputs of the first lever sensor 23 as the target height position of the working device and the outputs of the lift arm sensor 24 as the actual height position of the working device.

  That is, when the lifting control means 21A executes arbitrary lifting control based on the operation of the first lifting lever 22, the working device can be lifted to an arbitrary height position corresponding to the operation position of the first lifting lever 22. it can.

  In addition, when the lifting control means 21A executes the forced lifting control based on the operation of the second lifting lever 25, the working device can be automatically lifted to the lifting upper limit position corresponding to the preset lifting upper limit value, The work device can be automatically lowered to an arbitrary height position corresponding to the operation position of the first elevating lever 22.

  Thereby, for example, when a working device such as a rotary tiller is connected to the rear portion of the tractor, the working device is operated so that a desired working depth can be obtained by operating the first elevating lever 22. When plowing work is performed by arbitrarily setting the position, and when starting the headland turning to turn the vehicle body at the heel during this cultivating work, the second elevating lever 25 is operated upward. The working device can be easily raised to the upper limit position. As a result, it is possible to easily avoid the occurrence of an inconvenience that the inside of the turn is dug due to the work device turning while grounding. Further, by operating the second lifting lever 25 downward immediately before the end of the headland turning, the working device can be easily lowered to an arbitrary working height position set by the operation of the first lifting lever 22. it can. As a result, the cultivation work can be resumed with the end of the headland turning.

  The first elevating lever 22 is a position-holding type that swings back and forth, and is disposed on the right side of the driver seat 7. The second raising / lowering lever 25 is a neutral return type that swings up and down, and is disposed on the lower right side of the steering wheel 6. A rotary potentiometer is employed for the first lever sensor 23 and the lift arm sensor 24. The second lever sensor 26 includes a first contact that is closed in conjunction with an upward operation of the second lift lever 25, and a first contact that is closed in conjunction with a downward operation of the second lift lever 25. A switch with two contacts is adopted.

  Based on the output of the electromagnetic pickup type rotation sensor 27 that detects the output rotation speed of the engine 1, the control device 21 receives information such as the output rotation speed of the engine 1 on the display panel 28 provided in the boarding operation unit 8. A display control means 21B for displaying with a tachometer (not shown) or the like is provided as a control program. The display control means 21B displays the display state of the liquid crystal display unit 30 provided in the display panel 28, the hour meter, the remaining amount of fuel, and the like based on the operation of the display changeover switch 29 provided in the vicinity of the display panel 28. And a state in which information on vehicle speed such as the number of gears and the vehicle speed is displayed.

  The control device 21 is provided with target rotational speed setting means 21C for setting the target rotational speed of the engine 1 as a control program. Further, the first map data in which the output of the pedal sensor 32 that detects the operation position of the accelerator pedal 31 and the engine speed are associated, the output of the lever sensor 34 that detects the operation position of the accelerator lever 33, and the engine speed are obtained. The second map data corresponding to each other, the third map data corresponding to the output of the upper limit setting unit 35 for setting the upper limit of the engine speed and the engine speed, and the like are provided.

  The target rotation speed setting means 21C selects an engine rotation speed (hereinafter referred to as pedal setting rotation speed) corresponding to the output of the pedal sensor 32 based on the output of the pedal sensor 32 and the first map data. Based on the output of the lever sensor 34 and the second map data, an engine speed corresponding to the output of the lever sensor 34 (hereinafter referred to as lever set speed) is selected. Based on the output of the upper limit setter 35 and the third map data, the engine speed corresponding to the output of the upper limit setter 35 (hereinafter referred to as the upper limit speed) is selected.

  Then, when the selected rotation speed and the lever setting rotation speed are lower than the upper limit rotation speed, the higher rotation speed of the pedal setting rotation speed and the lever setting rotation speed is calculated. Set to the target speed. When either one of the pedal set speed and the lever set speed is higher than the upper limit speed, the upper limit speed is set to the target speed.

  The accelerator pedal 31 is a step-down operation type initial position return type and is provided at the right foot portion of the boarding operation unit 8. The accelerator lever 33 is a position-holding type that swings back and forth, and is disposed on the right side of the driver seat 7. The upper limit setting device 35 is configured as a dial type using a rotary potentiometer or the like.

  In the ECU 16, the target rotational speed is output from the engine 1 based on the target rotational speed set by the target rotational speed setting means 21 </ b> C of the control device 21, the output of the rotation sensor 27 input via the control device 21, and the like. A fuel injection control means 16A for controlling the operation of the supply pump 12, each injector 14 and the like so as to be obtained as the rotation speed is provided as a control program.

  The target engine speed setting means 21C of the control device 21 and the fuel injection control means 16A of the ECU 16 constitute an engine speed control means (an example of a control means) 36 for controlling the output speed of the engine 1.

  The engine speed control means 36 sets the pedal set speed to the target speed when the pedal set speed is higher than the lever set speed when the pedal set speed and the lever set speed are lower than the upper limit speed. And the foot accelerator control for controlling the output rotational speed of the engine 1 is executed so that the set rotational speed of the pedal is obtained as the output rotational speed of the engine 1. Conversely, when the lever set speed is higher than the pedal set speed, the engine 1 is set so that the lever set speed is set as the target speed and the lever set speed is obtained as the output speed of the engine 1. Execute hand accelerator control to control the output rotation speed. When either one of the pedal set speed and the lever set speed is higher than the upper limit speed, the upper limit speed is set to the target speed, and the upper limit speed is the output speed of the engine 1. The upper limit rotation control for controlling the output rotation speed of the engine 1 is executed.

  With this configuration, for example, by operating the accelerator lever 33 to an arbitrary operation position and operating the upper limit setting device 35 so that the upper limit rotational speed is not lower than the lever setting rotational speed, the output rotational speed of the engine 1 The vehicle body can be driven in a lever constant speed state in which is maintained at the lever set rotation speed. In this lever constant speed state, by operating the accelerator pedal 31 so that the pedal setting speed is higher than the lever setting speed, the output speed of the engine 1 is set to the lever setting speed during the operation. Thus, the vehicle body can be driven in a pedal acceleration state where the speed is increased to the pedal set rotational speed. In this pedal acceleration state, when the pedal set rotational speed becomes higher than the upper limit rotational speed, the vehicle body can be driven in an upper limited speed state in which the output rotational speed of the engine 1 is limited to the upper limit rotational speed. Then, by releasing the operation of the accelerator pedal 31, it is possible to easily return to the lever constant speed state.

  That is, it is possible to obtain a two-stage constant speed state of a lever constant speed state and an upper limited speed state, and it is possible to perform an arbitrary speed change operation over the lever constant speed state and the upper limited speed state.

  In the lever constant speed state, the upper limit setter 35 is operated so that the upper limit rotational speed is lower than the lever set rotational speed, thereby driving the vehicle body in the upper limited speed state where the rotational speed is lower than the lever constant speed state. Can be made. In this upper limited speed state, the upper limit setter 35 is operated so that the upper limit rotational speed is higher than the lever set rotational speed, whereby the lever can be easily returned to the constant speed state.

  That is, it is possible to finely adjust the constant speed rotational speed by operating the upper limit setter 35 based on the lever set rotational speed. As a result, it is possible to easily change the setting of the constant speed rotation speed according to the state of the field.

  Further, for example, if the accelerator lever 33 is operated to the idling position and the upper limit setting device 35 is operated so that the upper limit rotation speed becomes an engine rotation speed suitable for work, the accelerator pedal 31 is operated to the operation limit position. As a result, the vehicle body can be driven in a limited speed state in which the output rotational speed of the engine 1 is maintained at the upper limit rotational speed suitable for work. In addition, in this limited speed state, the operation of the accelerator pedal 31 is loosened so that the pedal set rotational speed is lower than the upper limit rotational speed, so that the vehicle body in the pedal deceleration state where the output rotational speed of the engine 1 is lower than the upper rotational speed Can be run. In this pedal deceleration state, it is possible to return to the upper limited speed state by operating the accelerator pedal 31 to the operation limit position again.

  In this way, if the upper limit setting device 35 is operated so that the upper limit rotational speed becomes an engine speed suitable for work, the accelerator pedal 31 is operated to the operation limit position during straight traveling during work, thereby A constant speed state suitable for work by the operation of the accelerator pedal 31 can be stably obtained regardless of the shaking of the vehicle body caused by the roughness. And when performing headland turning, the deceleration state suitable for headland turning can be easily acquired by loosening operation of the accelerator pedal 31 before starting headland turning. In addition, when a slip occurs in a constant speed state, it is possible to weaken the degree of slip and increase the grip force by loosening the operation of the accelerator pedal 31 and lowering the engine speed. You can escape. And the constant speed state suitable for work is easily reproducible by operating the accelerator pedal 31 to an operation limit position after the headland turning or after escape from a slip state.

  That is, it is possible to easily obtain a traveling state suitable for a reciprocating operation that repeats a straight traveling and a headland turning, and a traveling state suitable for a heavy traction operation in which a work device such as a plow or a subsoiler that is prone to slip is connected. .

  The control device 21 includes a first stored rotational speed that is read based on an operation of the first switch 37 that is a momentary switch disposed on the right side of the driver's seat 7, and a first memory that is a momentary switch that is disposed adjacent to the first switch 37. 2 and a second stored rotational speed that is read based on the operation of the switch 38.

  The target speed setting means 21C basically operates the first switch 37 in the lever constant speed state in which the accelerator lever 33 is operated at the operating position where the output speed of the engine 1 is higher than the idling speed. Then, based on the output of the first switch 37, the first stored rotational speed is set to the target rotational speed. When the first switch 37 is operated in a state where the first stored rotational speed is set to the target rotational speed, the time until the first switch 37 returns to the initial position is measured, and the measured time is within the set time ( (For example, within 3 seconds), the pedal setting speed, lever setting speed and upper limit speed are compared based on the output of the first switch 37 at that time, and the pedal setting speed and lever setting speed are When the rotation speed is lower than the upper limit rotation speed, the higher rotation speed of the pedal setting rotation speed and the lever setting rotation speed is set as the target rotation speed. When either one of the pedal set speed and the lever set speed is higher than the upper limit speed, the upper limit speed is set to the target speed.

  Further, when the second switch 38 is operated in the lever constant speed state in which the accelerator lever 33 is operated at the operation position where the output rotational speed of the engine 1 is higher than the idling rotational speed, the second switch 38 is operated based on the output of the second switch 38. The second stored rotational speed is set as the target rotational speed. When the second switch 38 is operated in a state where the second stored rotational speed is set to the target rotational speed, the time until the second switch 38 returns to the initial position is measured, and the measured time is within the set time ( (For example, within 3 seconds), the pedal setting speed, lever setting speed and upper limit speed are compared based on the output of the second switch 38 at that time, and the pedal setting speed and lever setting speed are When the rotation speed is lower than the upper limit rotation speed, the higher rotation speed of the pedal setting rotation speed and the lever setting rotation speed is set as the target rotation speed. When either one of the pedal set speed and the lever set speed is higher than the upper limit speed, the upper limit speed is set to the target speed.

  That is, when the first switch 37 is operated in the lever constant speed state, the engine speed control means 36 sets the first stored rotational speed to the target rotational speed, and the first stored rotational speed is the output rotational speed of the engine 1. First constant rotation control for controlling the output rotation speed of the engine 1 so as to be obtained as a number is executed. When the second switch 38 is operated in the lever constant speed state, the second stored rotational speed is set to the target rotational speed, and the output of the engine 1 is obtained so that the second stored rotational speed is obtained as the output rotational speed of the engine 1. Second constant rotation control for controlling the rotation speed is executed.

  In addition, during the execution of the first constant rotation control, when the first switch 37 is pressed shortly so that the measurement time until the first switch 37 returns to the initial position is within the set time, the first switch 37 The constant rotation control is terminated, and one of the foot accelerator control, the hand accelerator control, and the upper limit rotation control is executed based on the target rotation speed set according to the operation state at that time. During the execution of the second constant rotation control, if a short pressing operation of the second switch 38 is performed in which the measurement time until the second switch 38 returns to the initial position is within the set time, the second constant rotation is performed. The control is terminated, and any one of the foot accelerator control, the hand accelerator control, and the upper limit rotation control is executed based on the target rotational speed set according to the operation state at that time.

  With this configuration, for example, if the first stored rotational speed is set to an engine rotational speed suitable for tillage work and the second stored rotational speed is set to an engine rotational speed suitable for scraping work, the output rotational speed of the engine 1 is After operating the accelerator lever 33 to an operating position higher than the idling rotational speed, the first switch 37 is operated to maintain the output rotational speed of the engine 1 at the first stored rotational speed suitable for tillage work. The vehicle body can be driven in a state (hereinafter referred to as a first stored constant speed state). Further, after the accelerator lever 33 is operated to the operation position where the output rotational speed of the engine 1 is higher than the idling rotational speed, the second switch 38 is operated, so that the output rotational speed of the engine 1 is suitable for the scraping work. The vehicle body can be driven in a constant speed state (hereinafter referred to as a second stored constant speed state) maintained at two stored rotational speeds.

  Then, if the accelerator lever 33 is operated so that the lever set rotation speed becomes an engine rotation speed suitable for headland turning, in the first memory constant speed state, the first switch is set before starting headland turning. By short-pressing 37, it is possible to easily obtain a deceleration state (hereinafter referred to as a lever deceleration state) by an accelerator lever 33 suitable for headland turning, and immediately before the end of headland turning or the end of headland turning. By operating the first switch 37 later, the first stored constant speed state suitable for the tilling work can be easily reproduced. Further, in the second stored constant speed state, the lever deceleration state can be easily obtained by pressing the second switch 38 for a short time before starting the headland turning. By operating the second switch 38 after the end of the ground turning, the second stored constant speed state suitable for the scraping work can be easily reproduced.

  When the second switch 38 is operated during execution of the first constant rotation control, the engine speed control means 36 shifts from the first constant rotation control to the second constant rotation control. When the first switch 37 is operated during the execution of the second constant rotation control, the second constant rotation control is shifted to the first constant rotation control.

  With this configuration, for example, if the first stored rotational speed is set to an engine rotational speed suitable for work and the second stored rotational speed is set to an engine rotational speed suitable for headland turning, the output rotational speed of the engine 1 is By operating the first switch 37 after operating the accelerator lever 33 to an operation position higher than the idling speed, the vehicle body can be driven in the first stored constant speed state suitable for work. Then, by operating the second switch 38 before starting the headland turning, it is possible to easily obtain the second stored constant speed state suitable for the headland turning. By operating the first switch 37 after the end of the first, the first stored constant speed state suitable for the work can be easily reproduced.

  If the pedal set rotational speed becomes higher than the first stored rotational speed during execution of the first constant rotational control, the engine rotational speed control means 36 performs foot accelerator control in preference to the first constant rotational control. If the pedal set rotational speed becomes lower than the first stored rotational speed during the priority execution of the foot accelerator control, the foot accelerator control is terminated and the first constant rotational control is resumed. Further, if the pedal set rotational speed becomes higher than the second stored rotational speed during the execution of the second constant rotational control, the foot accelerator control is performed in preference to the second constant rotational control. If the pedal set rotational speed becomes lower than the second stored rotational speed during the priority execution of the foot accelerator control, the foot accelerator control is terminated and the second constant rotational control is resumed.

  With this configuration, in the first stored constant speed state, by operating the accelerator pedal 31 so that the pedal set rotational speed is higher than the first stored rotational speed, the output rotation of the engine 1 is performed during the operation. The vehicle body can be driven in a pedal speed increasing state in which the number is increased from the first stored rotational speed to the pedal setting rotational speed. In this pedal acceleration state, when the pedal set rotational speed becomes higher than the upper limit rotational speed, the vehicle body can be driven in an upper limited speed state in which the output rotational speed of the engine 1 is limited to the upper limit rotational speed. Then, the first stored constant speed state can be restored by releasing the operation of the accelerator pedal 31.

  Further, in the second stored constant speed state, by operating the accelerator pedal 31 so that the pedal set rotational speed is higher than the second stored rotational speed, the output rotational speed of the engine 1 is reduced during the operation. The vehicle body can be driven in a pedal acceleration state in which the second stored rotational speed is increased to the pedal setting rotational speed. In this pedal acceleration state, when the pedal set rotational speed becomes higher than the upper limit rotational speed, the vehicle body can be driven in an upper limited speed state in which the output rotational speed of the engine 1 is limited to the upper limit rotational speed. Then, the second stored constant speed state can be restored by releasing the operation of the accelerator pedal 31.

  The engine speed control means 36 ends the first constant speed control when the lever set speed decreases to the idling speed or less during execution of the first constant speed control, and sets it according to the operation state at that time. One of foot accelerator control, hand accelerator control, and upper limit rotation control is executed based on the target rotation speed. Further, when the lever set rotational speed falls below the idling rotational speed during the execution of the second constant rotational control, the second constant rotational control is terminated and based on the target rotational speed set according to the operation state at that time. One of foot accelerator control, hand accelerator control and upper limit rotation control is executed.

  With this configuration, in a constant speed state where the output rotational speed of the engine 1 is maintained at the first stored rotational speed or the second stored rotational speed, the accelerator lever 33 is operated so that the lever set rotational speed is equal to or less than the idling rotational speed. As a result, as long as the accelerator pedal 31 is not operated, it is possible to obtain a deceleration state in which the output rotational speed of the engine 1 is reduced to the idling rotational speed or less.

  In other words, when it is necessary to decelerate in the stored constant speed state in which the output rotational speed of the engine 1 is maintained at the first stored rotational speed or the second stored rotational speed, similarly to the deceleration operation in the lever constant speed state. The vehicle speed can be reduced by a familiar operation such as operating the accelerator lever 33 in the deceleration direction.

  When the lever set rotational speed becomes higher than the first stored rotational speed during execution of the first constant rotational control, the engine rotational speed control means 36 terminates the first constant rotational control and, depending on the operation state at that time, One of foot accelerator control, hand accelerator control, and upper limit rotation control is executed based on the set target rotational speed. If the lever set rotational speed becomes higher than the second stored rotational speed during execution of the second constant rotational control, the second constant rotational control is terminated and the target rotational speed set in accordance with the operation state at that time is set. Based on this, one of foot accelerator control, hand accelerator control, and upper limit rotation control is executed.

  With this configuration, when the lever set rotational speed is equal to or lower than the first stored rotational speed in the first stored constant speed state, the accelerator lever 33 is operated so that the lever set rotational speed is higher than the first stored rotational speed. As a result, the vehicle body can be driven in an accelerated state in which the output rotational speed of the engine 1 is increased to a lever set rotational speed or an upper limit rotational speed that is higher than the first stored rotational speed, and the speed after the speed increase. The vehicle can be driven at a constant speed.

  In the second stored constant speed state, when the lever set rotational speed is equal to or lower than the second stored rotational speed, the accelerator lever 33 is operated so that the lever set rotational speed is higher than the second stored rotational speed. Thus, the vehicle body can be driven in an accelerated state in which the output rotational speed of the engine 1 is increased to a lever setting rotational speed or an upper limit rotational speed that is higher than the second stored rotational speed, and at the speed after the speed increase Can be driven at a constant speed.

  In other words, when it is necessary to increase the speed in the constant speed state in which the output speed of the engine 1 is maintained at the first stored speed or the second stored speed, the same as the speed increasing operation in the lever constant speed state. In addition, the vehicle speed can be increased and maintained by a familiar operation such as operating the accelerator lever 33 in the speed increasing direction.

  When the upper limit rotational speed becomes lower than the first stored rotational speed during the execution of the first constant rotational control, the engine rotational speed control means 36 executes the upper limit rotational control in preference to the first constant rotational control. If the upper limit rotational speed becomes higher than the first stored rotational speed during the priority execution of the upper limit rotational control, the upper limit rotational control is terminated and the first constant rotational control is resumed. Further, when the upper limit rotational speed becomes lower than the second stored rotational speed during the execution of the second constant rotational control, the upper limit rotational control is executed in preference to the second constant rotational control. If the upper limit rotational speed becomes higher than the second stored rotational speed during the priority execution of the upper limit rotational control, the upper limit rotational control is terminated and the second constant rotational control is resumed.

  That is, by operating the upper limit setting unit 35 so that the upper limit rotational speed is lower than the first stored rotational speed in the first stored constant speed state, the upper limited speed having a rotational speed lower than that in the first stored constant speed state. The vehicle body can be driven in a state. In this upper limited speed state, the upper limit setting device 35 is operated so that the upper limit rotational speed is higher than the first stored rotational speed, so that the first stored constant speed state can be easily restored.

  Further, in the second stored constant speed state, by operating the upper limit setting unit 35 so that the upper limit rotational speed is lower than the second stored rotational speed, the upper limited speed having a lower rotational speed than in the second stored constant speed state. The vehicle body can be driven in a state. In this upper limited speed state, it is possible to easily return to the second stored constant speed state by operating the upper limit setter 35 so that the upper limit rotational speed is higher than the second stored rotational speed.

  With this configuration, it is possible to finely adjust the constant speed rotational speed by operating the upper limit setting device 35 based on the first stored rotational speed or the second stored rotational speed. As a result, it is possible to easily change the setting of the first stored rotational speed or the second stored rotational speed in accordance with the state of the field.

  In addition, when slip occurs in the first stored constant speed state, the upper limit setter 35 is operated so that the upper limit rotational speed becomes lower than the first stored rotational speed, and the second stored constant speed state In the case where slip occurs, the upper limit setter 35 is operated so that the upper limit rotational speed is lower than the second stored rotational speed, thereby reducing the degree of slip and increasing the grip force. Escape from easily. After the escape from the slip state, the upper limit rotational speed is higher than the first stored rotational speed in the first stored constant speed state, and the upper limit rotational speed is stored in the second stored constant speed state. By operating the upper limit setter 35 so as to be higher than the rotational speed, the first stored constant speed state or the second stored state in which the output rotational speed of the engine 1 is maintained at the first stored rotational speed or the second stored rotational speed. It can be returned to the constant speed state.

  Based on the operation of the first switch 37 or the second switch 38, the engine speed control means 36 changes from the first constant rotation control or the second constant rotation control to any one of the foot accelerator control, hand accelerator control, and upper limit rotation control. When the output rotational speed of the engine 1 increases due to the shift, the engine rotational speed changes more than when the output rotational speed of the engine 1 is decreased based on the operation of the first switch 37 or the second switch 38. The output rotational speed of the engine 1 is controlled so that the speed is reduced.

  Thereby, the change of the output rotational speed when the output rotational speed of the engine 1 increases becomes gentler than the case where the output rotational speed of the engine 1 decreases. As a result, it is possible to make the change in speed at the time of increased speed driving that increases the output speed of the engine smoother than at the time of reduced speed driving that decreases the output speed of the engine. Can be improved.

  The engine speed control means 36 is configured to perform a long press operation of the first switch 37 during which the measurement time until the first switch 37 returns to the initial position exceeds the set time during execution of the first constant rotation control. Then, based on the output of the first switch 37 at that time, the process shifts from the first constant rotation control to the first stored rotation speed change control that enables the setting change of the first stored rotation speed. In addition, during the execution of the second constant rotation control, if a long press operation of the second switch 38 is performed for which the measurement time until the second switch 38 returns to the initial position exceeds the set time, Based on the output of the second switch 38, the process shifts from the second constant rotation control to the second stored rotation speed change control that enables the setting change of the second stored rotation speed.

  In the first stored rotational speed change control, when a short press operation of the first switch 37 is performed, the first stored rotational speed is increased by a certain rotational speed (for example, 10 rpm) based on the output of the first switch 37 at that time. Let When a short press operation of the second switch 38 is performed, the first stored rotational speed is decreased by a certain rotational speed (for example, 10 rpm) based on the output of the second switch 38 at that time. When the long press operation of the first switch 37 is performed, the output is continued based on the output of the first switch 37 at that time (while the long press operation of the first switch 37 is performed). The first stored rotational speed is continuously increased. When the long pressing operation of the second switch 38 is performed, the output is continued based on the output of the second switch 17 at that time (while the long pressing operation of the second switch 38 is performed). The first stored rotational speed is continuously reduced. If neither the operation of the first switch 37 nor the operation of the second switch 38 is performed for a set time (for example, 3 seconds), the rotational speed at that stage is determined as the first stored rotational speed. Then, the first stored rotation speed change control is shifted to the first constant rotation control.

  In the second stored rotational speed change control, when a short press operation of the first switch 37 is performed, the second stored rotational speed is increased by a certain rotational speed (for example, 10 rpm) based on the output of the first switch 37 at that time. Let When a short press operation of the second switch 38 is performed, the second stored rotational speed is decreased by a certain rotational speed (for example, 10 rpm) based on the output of the second switch 38 at that time. When the long press operation of the first switch 37 is performed, the output is continued based on the output of the first switch 37 at that time (while the long press operation of the first switch 37 is performed). The second stored rotational speed is continuously increased. When the long pressing operation of the second switch 38 is performed, the output is continued based on the output of the second switch 17 at that time (while the long pressing operation of the second switch 38 is performed). The second stored rotational speed is continuously reduced. If neither the operation of the first switch 37 nor the operation of the second switch 38 is performed for a set time (for example, 3 seconds), the rotational speed at that stage is determined as the second stored rotational speed. Then, the second stored rotation speed change control is shifted to the second constant rotation control.

  That is, the first switch 37 and the second switch 38 are instructed to command the execution of the first constant rotation control or the second constant rotation control, the transition from the first constant rotation control to the first stored rotation speed change control, or The command means for instructing the transition from the second constant rotation control to the second stored rotational speed change control, and the setting device for changing the setting of the first stored rotational speed or the second stored rotational speed. Thereby, compared with the case where the operation tool corresponding to each is provided, cost reduction and reduction of installation space can be aimed at.

  The engine speed control means 36 executes the first stored speed change control when the long press operation of the first switch 37 is performed at the power-on stage when the key switch 39 is operated to the ON position, When a long press operation of the switch 38 is performed, the second stored rotational speed change control is executed. Thereby, the first stored rotational speed and the second stored rotational speed can be changed according to the work or the like before the work starts.

  As shown in FIG. 2 and FIG. 3, when the first switch 37 is operated in a state where the first constant rotation control can be performed, the engine speed control means 36 displays a display according to the pressing operation at that time. Display information is transmitted to the control means 21B, and in the liquid crystal display unit 30, the first stored rotational speed (here, “1800” is illustrated) and the first identification symbol 40 indicating the first stored rotational speed. (Here, “A” is illustrated) and a second identification symbol 41 (here, “AUTO” is illustrated) indicating the execution of the first constant rotation control or the second constant rotation control. [See FIG. 3A]. Then, the first constant rotation control is started with the return of the first switch 37 to the initial position.

  In addition, when the second switch 38 is operated in a state where the second constant rotation control can be performed, display information is transmitted to the display control unit 21B in accordance with the pressing operation at that time, and the liquid crystal display unit 30 A second stored rotational speed (here, “1000” is illustrated), a first identification symbol 40 (here, “B” is illustrated) indicating the second stored rotational speed, and a first A second identification symbol 41 (here, “AUTO”) indicating the execution of the constant rotation control or the second constant rotation control is continuously displayed (see FIG. 3B). Then, the second constant rotation control is started with the return of the second switch 38 to the initial position.

  That is, the output rotation speed of the engine 1 is changed with the start of the first constant rotation control or the second constant rotation control without providing a dedicated display unit for displaying the first storage rotation speed, the second storage rotation speed, and the like. In a stage before being performed, the target rotational speed and the like in the constant rotation control can be displayed on the liquid crystal display unit 30 to be visually recognized by the driver. Further, in accordance with the operation of the first switch 37 or the second switch 38, the display state of the liquid crystal display unit 30 is switched to a state in which the target rotational speed in the first constant rotation control or the second constant rotation control is displayed. Thus, it is possible to make it easier for the driver to visually recognize the target rotational speed or the like in the first constant rotation control or the second constant rotation control.

  When the first switch 37 is operated in a state where the accelerator lever 33 is positioned at an operation position where the output rotational speed of the engine 1 is equal to or lower than the idling rotational speed, the engine rotational speed control means 36 One stored rotational speed (here “1800”), first identification symbol 40 (here “A”) and second identification symbol 41 (here “AUTO”) are displayed intermittently (see FIG. 3C). ].

  Further, when the second switch 38 is operated in a state where the accelerator lever 33 is positioned at an operation position where the output rotational speed of the engine 1 is equal to or lower than the idling rotational speed, the second storage rotational speed (here, Then, “1000”), the first identification symbol 40 (here “B”), and the second identification symbol 41 (here “AUTO”) are displayed intermittently (see FIG. 3D).

  As a result, the accelerator lever 33 is positioned at the operation position where the output rotational speed of the engine 1 is equal to or lower than the idling rotational speed, so that the first constant rotational control or the first The driver can visually recognize that the two constant rotation control is not executed.

  When the first switch 37 is pressed for a short time during the execution of the first constant rotation control in which the first stored rotation speed is set to the target rotation speed, the engine speed control means 36 is accompanied by the pressing operation at that time. Display information is transmitted to the display control means 21B, and the liquid crystal display unit 30 replaces the first stored rotational speed with a target rotational speed (here, “1500”) that is set according to the operation state after the completion of the first constant rotational control. Are displayed continuously and the display of the first identification symbol 40 is terminated (see (A) and (E) of FIG. 3). Then, the first constant rotation control is terminated with the return of the first switch 37 to the initial position, and one of foot accelerator control, hand accelerator control, and upper limit rotation control corresponding to the operation state at that time is started. To do.

  Further, when the second switch 38 is pressed for a short time during the execution of the second constant rotation control with the second stored rotation speed set to the target rotation speed, the display control means 21B displays the second switch 38 in response to the pressing operation at that time. The information is transmitted, and the liquid crystal display unit 30 continuously displays the target rotational speed (here, “1500”) set according to the operation state after the end of the second constant rotational control, instead of the second stored rotational speed. Then, the display of the first identification symbol 40 is terminated [see (B) and (E) of FIG. 3]. Then, the second constant rotation control is terminated with the return of the second switch 37 to the initial position, and one of the foot accelerator control, the hand accelerator control, and the upper limit rotation control according to the operation state at that time is started. To do.

  That is, in the stage before the output rotation speed of the engine 1 is changed in accordance with the transition from the first constant rotation control or the second constant rotation control to any one of the foot accelerator control, the hand accelerator control, and the upper limit rotation control. The target rotation speed after the end of the first constant rotation control or the second constant rotation control can be displayed on the liquid crystal display unit 30 so that the driver can visually recognize it.

  When the second switch 38 is operated during the execution of the first constant rotation control, the engine speed control means 36 transmits display information to the display control means 21B in accordance with the pressing operation at that time, and the liquid crystal display unit 30, the second stored rotational speed (here “1000”) is continuously displayed instead of the first stored rotational speed (here “1800”), and the first identification symbol 40 indicates the first stored rotational speed. (Here “A”) is changed to one indicating the second stored rotational speed (here “B”) (see FIGS. 3A and 3B). Then, the first constant rotation control is shifted to the second constant rotation control with the return of the second switch 38 to the initial position.

  When the first switch 37 is operated during the execution of the second constant rotation control, display information is transmitted to the display control means 21B in accordance with the pressing operation at that time, and the liquid crystal display unit 30 stores the second information. Instead of the rotational speed (here “1000”), the first stored rotational speed (here “1800”) is continuously displayed, and the first identification symbol 40 indicates the second stored rotational speed (here “B”). ) To a value indicating the first stored rotational speed (here, “A”) (see (B) and (A) of FIG. 3). Then, with the return of the first switch 37 to the initial position, the second constant rotation control is shifted to the first constant rotation control.

  That is, at the stage before the output rotational speed of the engine 1 is changed in accordance with the transition from the first constant rotation control to the second constant rotation control or from the second constant rotation control to the first constant rotation control, The target rotation speed in the first constant rotation control or the second constant rotation control can be displayed on the liquid crystal display unit 30 so that the driver can visually recognize it.

  When the pedal set rotational speed becomes higher than the first stored rotational speed during execution of the first constant rotational control, the engine rotational speed control means 36 performs foot accelerator control in preference to the first constant rotational control, and displays Display information is transmitted to the control means 21B, and the display of the second identification symbol 41 (here, “AUTO”) on the liquid crystal display unit 30 is changed from continuous display to intermittent display (see FIGS. 3A and 3F). ].

  If the pedal set rotational speed becomes lower than the first stored rotational speed during the priority execution of the foot accelerator control, the foot accelerator control is terminated and the first constant rotational control is resumed, and the display information is transmitted to the display control means 21B. Then, the display of the second identification symbol 41 (here, “AUTO”) on the liquid crystal display unit 30 is changed from the intermittent display to the continuous display (see (F) and (A) of FIG. 3).

  Further, when the pedal set rotational speed becomes higher than the second stored rotational speed during execution of the second constant rotational control, the foot accelerator control is performed in preference to the second constant rotational control, and display information is displayed on the display control means 21B. And the display of the second identification symbol 41 (here, “AUTO”) on the liquid crystal display unit 30 is changed from continuous display to intermittent display (see FIGS. 3B and 3G).

  If the pedal set rotational speed becomes lower than the second stored rotational speed during the priority execution of the foot accelerator control, the foot accelerator control is terminated and the second constant rotational control is restarted, and the display information is transmitted to the display control means 21B. Then, the display of the second identification symbol 41 (here, “AUTO”) on the liquid crystal display unit 30 is changed from the intermittent display to the continuous display (see (G) and (B) of FIG. 3).

  That is, when the first constant rotation control or the second constant rotation control is shifted to the foot accelerator control by the operation of the accelerator pedal 31 during the execution of the first constant rotation control or the second constant rotation control, the liquid crystal display unit 30 The first constant rotation control or the second constant rotation is performed by intermittently displaying the second identification symbol 41 while continuously displaying the first storage rotation number or the second storage rotation number and the first identification symbol 40 indicating the first storage rotation number. The driver can visually recognize the transition from the control to the foot accelerator control. Further, when the first constant rotation control or the second constant rotation control is resumed by the operation of the accelerator pedal 31 during the priority execution of the foot accelerator control, the liquid crystal display unit 30 uses the first stored rotation speed or the second stored rotation. By continuously displaying the numbers and the first identification symbol 40 and the second identification symbol 41 corresponding to the numbers, the first constant rotation control or the second constant rotation control is resumed, and the first constant rotation control or the second constant is resumed. The driver can visually recognize the target rotation speed in the constant rotation control.

  The engine speed after the shift to the foot accelerator control can be visually confirmed with a tachometer.

  When the upper limit rotational speed becomes lower than the first stored rotational speed during execution of the first constant rotational control, the engine rotational speed control means 36 executes the upper limit rotational control in preference to the first constant rotational control, and performs display control. Display information is transmitted to the means 21B, and the upper limit number of rotations (here, “1700” is exemplified) is continuously displayed on the liquid crystal display unit 30 instead of the first stored number of rotations (here, “1800”). The first identification symbol 40 is changed from one indicating the first stored rotation number (here “A”) to one indicating the upper limit rotation number (here “L” is illustrated), and the second identification symbol 41 is changed. Is changed from one indicating the execution of the first constant rotation control or the second constant rotation control (here, “AUTO”) to one indicating the priority execution of the upper limit rotation control (here, “↑ AUTO” is illustrated) [Refer to Fig. 3 (A) and (H) ].

  If the upper limit rotational speed becomes higher than the first stored rotational speed during the priority execution of the upper limit rotational control, the upper limit rotational control is terminated and the first constant rotational control is resumed, and display information is transmitted to the display control means 21B. In the liquid crystal display unit 30, instead of the upper limit rotational speed (here “1700”), the first stored rotational speed (here “1800”) is continuously displayed, and the first identification symbol 40 indicates the upper limit rotational speed. (Here, “L”) is changed to one indicating the first stored rotational speed (here, “A”), and the second identification symbol 41 indicates priority execution of the upper limit rotational control (here “↑ AUTO”) ) Is changed to one indicating execution of the first constant rotation control or the second constant rotation control (here, “AUTO”) (see (H) and (A) in FIG. 3).

  When the upper limit rotational speed becomes lower than the second stored rotational speed during the execution of the second constant rotational control, the upper limit rotational control is executed in preference to the second constant rotational control, and display information is displayed on the display control means 21B. In the liquid crystal display unit 30, instead of the second stored rotational speed (here, “1000”), the upper limit rotational speed (here, “900” is illustrated) is continuously displayed, and the first identification symbol 40 is displayed. The second storage speed is changed from the one indicating the second stored rotational speed (here “B”) to the one indicating the upper limit rotational speed (here “L”), and the second identification symbol 41 is changed to the first constant rotational control or the second constant rotational speed. The one indicating the execution of the rotation control (here “AUTO”) is changed to the one indicating the priority execution of the upper limit rotation control (here “↑ AUTO”) (see FIGS. 3B and 3I).

  If the upper limit rotational speed becomes higher than the second stored rotational speed during the priority execution of the upper limit rotational control, the upper limit rotational control is terminated and the second constant rotational control is resumed, and display information is transmitted to the display control means 21B. In the liquid crystal display unit 30, instead of the upper limit rotational speed (here, “900”), the second stored rotational speed (here, “1000”) is continuously displayed, and the first identification symbol 40 indicates the upper limit rotational speed. (Here, “L”) is changed to one indicating the second stored rotational speed (here, “B”), and the second identification symbol 41 indicates priority execution of the upper limit rotational control (here “↑ AUTO”) ) Is changed to one indicating execution of the first constant rotation control or the second constant rotation control (here, “AUTO”) (see (I) and (B) in FIG. 3).

  In other words, when the upper limit setting device 35 is operated during the execution of the first constant rotation control or the second constant rotation control, when the first constant rotation control or the second constant rotation control is shifted to the upper limit rotation control, the liquid crystal display unit 30 is used. , By continuously displaying the upper limit rotational speed, the first identification symbol 40 indicating the upper limit rotational speed, and the second identification symbol 41 indicating the priority execution of the upper limit rotational control, the shift to the upper limit rotational control and the engine 1 at that time The driver can visually recognize the output rotation speed. Further, when the first constant rotation control or the second constant rotation control is resumed by operating the upper limit setting device 35 during the priority execution of the upper limit rotation control, the liquid crystal display unit 30 uses the first stored rotation speed or the second storage speed. The first constant rotation control or the second constant rotation is displayed by continuously displaying the rotation speed, the first identification symbol 40 indicating the rotation number, and the second identification symbol 41 indicating the execution of the first constant rotation control or the second constant rotation control. The driver can visually recognize the resumption of control and the target rotation speed in the first constant rotation control or the second constant rotation control to be resumed.

  When the first switch 37 is operated when the upper limit rotational speed is lower than the first stored rotational speed or when the pedal setting rotational speed is higher than the first stored rotational speed, the engine rotational speed control means 36 performs the operation. Accordingly, display information is transmitted to the display control means 21B, and the first storage rotational speed (here, “1800”) is intermittently displayed on the liquid crystal display unit 30, and the first identification symbol 40 (here, “A”) is displayed. The second identification symbol 41 (here, “AUTO”) is continuously displayed [see (J) in FIG. 3].

  When the second switch 38 is operated when the upper limit rotational speed is lower than the second stored rotational speed or when the pedal setting rotational speed is higher than the second stored rotational speed, the display control means is accompanied by the operation. Display information is transmitted to 21B, and the second storage rotational speed (here, “1000”) is displayed intermittently on the liquid crystal display unit 30, and the first identification symbol 40 (here, “B”) and the second identification symbol 41 ( Here, “AUTO”) is continuously displayed (see (K) of FIG. 3).

  Accordingly, the first constant rotation control or the second constant rotation control is not executed regardless of the operation of the first switch 37 or the second switch 38 due to the operation position of the accelerator pedal 31 or the upper limit setting device 35. This can be visually recognized by the driver.

  When the first switch 37 is pressed for a long time during the execution of the first constant speed control, the engine speed control means 36 shifts from the first constant speed control to the first stored speed change control, and the display control means. Display information is transmitted to 21B, and the display of the first identification symbol 40 (here “A”) and the second identification symbol 41 (here “AUTO”) on the liquid crystal display unit 30 is changed from continuous display to intermittent display [ See FIGS. 3A and 3L].

  Further, when the second switch 38 is pressed for a long time during the execution of the second constant rotation control, the second constant rotation control is shifted to the second stored rotation speed change control and the display information is transmitted to the display control means 21B. Then, the display of the first identification symbol 40 (here “B”) and the second identification symbol 41 (here “AUTO”) on the liquid crystal display unit 30 is changed from continuous display to intermittent display [(B) of FIG. And (M)].

  Thus, by operating the first switch 37 or the second switch 38, the first stored rotation speed change control or the second stored rotation speed change control is shifted from the first constant rotation control or the second constant rotation control to the first stored rotation speed change control. It is possible to make the driver visually recognize that the setting change of the stored rotational speed or the second stored rotational speed is possible.

  When the first switch 37 or the second switch 38 is operated during the execution of the first stored rotational speed change control or the second stored rotational speed change control, the engine speed control means 36, based on the operation at that time, While changing 1st memory | storage rotation speed or 2nd memory | storage rotation speed, display information is transmitted to the display control means 21B, and the 1st memory | storage rotation speed or 2nd memory | storage rotation speed after a change is continuously displayed on the liquid crystal display part 30. .

  Thereby, the setting change of the 1st memory | storage rotation speed or the 2nd memory | storage rotation speed by operation of the 1st switch 37 or the 2nd switch 38 can be performed visually.

  When the display switch 42 provided in the boarding operation unit 8 is operated, the engine speed control unit 36 transmits display information to the display control unit 21B, and displays the display on the liquid crystal display unit 30 in the first storage speed ( Here, “1800”), the first identification symbol 40 (here “A”), and the second identification symbol 41 (here “AUTO”) are continuously displayed, and the second stored rotational speed (here “1000”). ”), The first identification symbol 40 (here“ B ”), and the second identification symbol 41 (here“ AUTO ”) are continuously displayed every set time (for example, 1 second).

  Various control programs, map data, the first storage rotational speed, the second storage rotational speed, and the like are stored in the storage means 21D including a nonvolatile memory such as an EEPROM or a flash memory provided in the control device 21. .

    [Another embodiment]

[1] The working vehicle may be a riding mower, a riding rice transplanter, a combine, or a wheel dozer.

[2] The work device equipped on the tractor may be a front loader, a grooving device, or a wrinkle coating device.

[3] The engine 1 may be a diesel engine or a gasoline engine.

[4] The control means 36 may be provided in the control device 21 or may be provided in the ECU 16. The control device 21 and the ECU 16 may be configured integrally.

[5] The command means 37 and 38 may be constituted by a neutral return type single switch having a first contact and a second contact. In this configuration, the closing operation of the first contact of the switch may be an operation for instructing the execution of the constant rotation control, and the closing operation of the second contact may be another operation for instructing the execution of the stored rotation speed change control. Also, a short closing operation of the first contact within the set time is an operation for instructing execution of the first constant rotation control, and a short closing operation of the second contact within the setting time is instructed to execute the second constant rotation control. The first contact long-close operation exceeding the set time is set as another operation for instructing execution of the first stored rotation speed change control, and the second contact long-close operation exceeding the set time is set as the second stored rotation speed. It is good also as another operation which instruct | indicates execution of change control.

[6] A single stored rotational speed may be stored in the storage means 21D, or three or more stored rotational speeds may be stored. In the case where a single stored rotational speed is stored in the storage means 21D, it is only necessary to provide a single command means 37. When a momentary switch is provided as the single command means 37, the engine stored in the storage means 21D when the control means 36 performs a short-pressing operation of the momentary switch during execution of the storage rotation speed change control. The engine speed is changed in a direction to increase by a predetermined speed, and when the momentary switch is pressed for a long time, the engine speed stored in the storage means 21D is changed to a direction to decrease by a predetermined speed. Also good.

[7] A dedicated operation tool for changing the stored rotational speed may be provided.

Overall side view of tractor Block diagram showing control configuration Diagram showing switching of display contents on the liquid crystal display

Explanation of symbols

1 Engine 21D Storage means 36 Control means 37 Command means 38 Command means

Claims (4)

An artificially operated command means for instructing reading of the engine speed stored in the storage means, and the engine speed stored in the storage means can be obtained as the engine output speed based on the operation of the command means. An engine rotation speed control structure for a work vehicle, comprising a control means for performing constant rotation control for controlling the output rotation speed,
When the control means performs another operation different from the operation, the control means enables the control means to change the setting of the engine speed stored in the storage means based on the other operation. An engine rotational speed setting structure for a work vehicle, characterized in that   2. The storage speed change control according to claim 1, wherein the control means is configured to change the engine speed stored in the storage means based on an operation of the command means. Engine speed setting structure of a working vehicle. The command means is composed of two momentary switches,
The storage means stores an engine speed corresponding to one momentary switch and an engine speed corresponding to the other momentary switch,
The operation is a short press operation within a set time of the momentary switch, and the other operation is a long press operation exceeding the set time of the momentary switch,
The control means is
Based on the short-pressing operation of the one momentary switch, the first constant rotation control for controlling the output rotation speed so that the engine rotation speed corresponding to the one momentary switch is obtained as the output rotation speed of the engine. Run as constant rotation control,
A second constant rotation control for controlling the output rotational speed so that an engine rotational speed corresponding to the other momentary switch is obtained as an output rotational speed of the engine based on the short pressing operation of the other momentary switch; Run as constant rotation control,
Based on the long-pressing operation of the one momentary switch, the first stored rotation speed change control that enables the setting change of the engine rotation speed corresponding to the one momentary switch stored in the storage means is stored in the stored rotation speed Run as change control,
Based on the long-pressing operation of the other momentary switch, the second stored rotation speed change control for enabling the setting change of the engine speed corresponding to the other momentary switch stored in the storage means is stored in the stored rotation speed. Run as change control,
In both the first stored rotational speed change control and the second stored rotational speed change control, the engine rotational speed to be controlled at that time is changed in a direction of increasing based on the operation of the one momentary switch. 3. The engine speed setting structure for a work vehicle according to claim 2, wherein the engine rotational speed setting structure is configured to change in a decreasing direction based on an operation of the other momentary switch. In any of the first stored rotational speed change control and the second stored rotational speed change control, the control means is
When the short pressing operation of the one momentary switch is performed, the engine speed to be controlled at that time is changed in a direction to increase by a predetermined speed,
When the short-pressing operation of the other momentary switch is performed, the engine speed to be controlled at that time is changed in a direction to decrease by a predetermined speed,
When the long-pressing operation of the one momentary switch is performed, while the operation is continued, the engine rotational speed to be controlled at that time is changed to a continuously increasing direction,
When the long-pressing operation of the other momentary switch is performed, the engine rotational speed to be controlled at that time is continuously changed so as to continuously decrease while the operation is continued. The engine speed setting structure for a work vehicle according to claim 3.

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