JP5927763B2 - Work vehicle - Google Patents

Description

  The present invention relates to a work vehicle that performs various operations by connecting a work machine such as a seedling transplanter to the rear part of a vehicle body, and belongs to the technical field of agricultural machinery.

  Conventionally, when a work vehicle connected to a farming machine such as a seedling transplanter, for example, moves the aircraft backward at the shore during seedling transplanting operation, the hand accelerator lever is operated to drive at a low vehicle speed. Therefore, the engine speed is often set to a low speed. However, when the engine speed is reduced in this way, the ascending speed of the lifting device that lifts and lowers the work implement driven by the power from the engine becomes slow. For this reason, it is necessary to wait for the vehicle to move backward at a position very close to the kite until it rises above the height at which the work implement does not contact the kite, resulting in a problem that work efficiency is reduced. In particular, when the weight of the work implement is large, there is a problem that the lifting speed of the elevating device becomes slow and more standby time is required.

  On the other hand, according to the backup device of the agricultural machine described in Patent Document 1, when the reverse operation is performed as described above, the work machine also automatically rises, but the rising speed is reduced due to the decrease in the engine speed. In order to avoid a reduction in work efficiency due to a decrease, the following configuration is disclosed.

  That is, when the hand accelerator lever of the travel transmission (for example, HST (hydrostatic stepless transmission)) is switched to the reverse stop position, the ascent speed of the work implement is increased only while the hand accelerator lever is in the stop position. Therefore, after the solenoid device is energized, the accelerator device is operated at a higher speed than normal, the engine speed is controlled to be higher than normal, and after moving to the reverse travel position, the original rotation set by the hand accelerator lever is performed. It has been reduced to a number. It is larger than the ascending speed before the hand accelerator lever is switched to the reverse stop position, and is configured to raise the work implement within a short time.

  That is, when the hand accelerator lever of the travel transmission is set at the reverse stop position, the ascent speed of the work implement is increased by controlling the engine speed to be higher than the engine speed during normal idling.

JP-A-7-123817

  However, in such a conventional agricultural machine backup device structure, the engine speed increases only when the hand accelerator lever is in the reverse stop position, so the operator cannot wait in the reverse standby state and the work machine is on the way up. In spite of this, when the hand accelerator lever is moved to the reverse low speed traveling, there is a risk that the work implement has not been lifted, and thus it will come into contact with a bag or the like. Moreover, in order to avoid this danger, it was still necessary to wait while the vehicle was stopped.

  The present invention has been made in view of the above-described problems of the conventional work vehicle, and provides a work vehicle capable of raising the work implement in a shorter time than the conventional during reverse travel while eliminating the need for a standby time in the travel stop state. To do.

In order to solve the above-mentioned problem, the present invention described in claim 1
A link mechanism (8) for mounting the work implement (7) on the rear part of the traveling vehicle body (2);
A lifting device (30) for lifting and lowering the link mechanism (8);
An engine (6) provided on the traveling vehicle body;
A transmission (5) for shifting and outputting the power of the engine (6);
A traveling operation lever (10) for operating the traveling speed by changing the output of the transmission by switching to any one of the forward traveling region, the stop region, and the reverse traveling region;
A control unit (200) for performing a first control for controlling the engine speed when the travel operation lever (10) is at least in the reverse travel range;
In the first control, the engine speed is set to be higher than the engine speed when the travel operation lever (10) is at the highest speed position where the travel speed is set to the highest in the reverse travel range. With the control configuration to increase the engine speed when in the front position ,
A rise detector (130) for detecting that the work implement (7) exceeds a predetermined height;
The control unit (200) performs the first control until the rise detection unit (130) detects the rise of the work implement (7), and the rise detection unit (130) performs the work implement (130). 7) After detecting the rise in 7), the control structure for setting the maximum engine speed when the travel operation lever (10) is in the highest speed position where the travel speed is set to the maximum in the reverse travel range. This is a work vehicle characterized by that.

The present invention according to claim 2
A link mechanism (8) for mounting the work implement (7) on the rear part of the traveling vehicle body (2);
A lifting device (30) for lifting and lowering the link mechanism (8);
An engine (6) provided on the traveling vehicle body;
A transmission (5) for shifting and outputting the power of the engine (6);
A traveling operation lever (10) for operating the traveling speed by changing the output of the transmission by switching to any one of the forward traveling region, the stop region, and the reverse traveling region;
A control unit (200) for performing a first control for controlling the engine speed when the travel operation lever (10) is at least in the reverse travel range;
In the first control, the engine speed is set to be higher than the engine speed when the travel operation lever (10) is at the highest speed position where the travel speed is set to the highest in the reverse travel range. With the control configuration to increase the engine speed when in the front position,
A sub-shift operation lever (140) for switching the operation of the work vehicle to at least one of a plurality of modes including a planting mode and a movement mode;
A lever position detection unit (150) for detecting an operation position of the auxiliary transmission operation lever (140);
When it is detected that the operation position is other than the planting mode, the control unit (200) does not perform the first control, and the travel operation lever (10) is within the reverse travel range, a work vehicle you characterized in that it is configured to control the maximum engine speed when in the highest speed position for setting the speed to the maximum.

Further, the present invention described in claim 3
A link mechanism (8) for mounting the work implement (7) on the rear part of the traveling vehicle body (2);
A lifting device (30) for lifting and lowering the link mechanism (8);
An engine (6) provided on the traveling vehicle body;
A transmission (5) for shifting and outputting the power of the engine (6);
A traveling operation lever (10) for operating the traveling speed by changing the output of the transmission by switching to any one of the forward traveling region, the stop region, and the reverse traveling region;
A control unit (200) for performing a first control for controlling the engine speed when the travel operation lever (10) is at least in the reverse travel range;
In the first control, the engine speed is set to be higher than the engine speed when the travel operation lever (10) is at the highest speed position where the travel speed is set to the highest in the reverse travel range. With the control configuration to increase the engine speed when in the front position,
When the travel operation lever (10) is switched to at least one position in the reverse travel area, the travel operation lever (10) is positioned at each of a plurality of switching positions corresponding to the first switching pattern. Lever positioning portions (310, 338a, 338a1),
When the travel operation lever (10) is switched to at least one position in the reverse travel area, the travel operation lever is moved at each of a plurality of switching positions corresponding to a second switching pattern different from the first switching pattern. A second lever positioning part (320, 338b, 338b1) for positioning;
The movement of the travel operation lever (10) is selectively transmitted to one of the first lever positioning part (310, 338a, 338a1) and the second lever positioning part (320, 338b, 338b1). Switching units (331, 332, 333, 334, 335) for
The position of the first stage of the reverse travel area of the second lever positioning portion (320, 338b, 338b1) is the first position of the reverse travel area of the first lever positioning portion (310, 338a, 338a1). a work vehicle you characterized in that a configuration is a position between the stage and the second stage.

Further, the present invention according to claim 4 provides
A speed detector (120) for detecting the travel speed;
The In no event travel operation lever (10) is in said reverse travel range, when the traveling speed is detected by the speed detecting unit that has reached a predetermined speed (120), wherein the control unit (200), the travel operation lever (10) be operated further to the highest speed position direction, one of claims 1 to 3, characterized in that the arrangement for controlling the engine speed so as to maintain said predetermined velocity The work vehicle according to claim 1.

Further, the present invention according to claim 5 provides:
When the travel operation lever (10) is operated to the reverse stop position on the reverse travel region side in the stop region, the work machine (7) is raised.
The control unit (200) determines the engine speed when the travel operation lever (10) is in the reverse stop position, and the minimum value when the travel operation lever (10) is in the reverse travel range. The work vehicle according to claim 1, 2, or 3, wherein the control configuration is set to be higher than the engine speed.

Further, the present invention according to claim 6 provides
A rotation speed operation unit (13) for increasing or decreasing the engine rotation speed;
The controller (200) is configured to increase the engine speed in preference to the first control when there is an operation to increase the engine speed by the speed operation section (13). a working vehicle according to claim 1, any one of the 5, characterized.

The present invention according to claim 7 provides
Mode selection for selecting any one of a plurality of control modes including at least a standard mode, a low fuel consumption mode, a high output mode, and a reverse mode capable of controlling the rotation of the engine (6) with different power characteristics. Part (170),
The control unit (200) controls the engine speed based on the reverse mode regardless of the selection result of the mode selection unit (170) when the travel operation lever (10) is in the reverse travel range. a work vehicle according to any one of claims 1 to 6, characterized in that a configuration in which.

According to the first aspect of the present invention, the work implement (7) can be raised in a shorter time than in the prior art during backward traveling while eliminating the waiting time in the traveling stop state. That is, when the travel operation lever (10) is operated to a position before the maximum speed position, the engine speed increases to a peak value, and when the travel operation lever (10) is operated to the maximum speed position, the engine rotation speed increases. By adopting the control configuration in which the number is reduced, it is possible to prevent the traveling speed from being excessively increased when the vehicle travels backward at a high speed, so that the operator can easily operate the traveling vehicle body (2) in the backward direction, and the working efficiency is improved.
Moreover, since the operating speed at which the engine speed increases to the peak value is provided, the ascending speed of the link mechanism (8) increases, so that the work machine (7) attached to the link mechanism (8) contacts the ground. Since this can be prevented, the working machine (7) is prevented from being damaged, and the durability of the working machine (7) is improved.
Further, when the ascending detection unit (130) is in the detection state, the lifting / lowering operation by the lifting / lowering device (30) is not necessary, and the control characteristic of another rotational speed that matches the engine rotational speed with the operation stage of the travel operation lever (10) Since the control configuration is changed to (see the engine speed control characteristic indicated by the one-dot chain line in FIG. 5A), an unnecessary increase in the engine speed can be prevented, so that the amount of fuel consumed In addition, since it is possible to prevent an unnecessary load from being applied to the constituent members, durability is improved.
Further, since the engine speed follows the control characteristic of the other speed according to the operation stage of the travel operation lever (10), it is prevented that the reverse speed is suddenly increased. ) To improve the operability.
And when the rise detection part (130) is in a non-detection state, in order to raise the link mechanism (8), the engine speed is increased to the peak value, so that the link mechanism (8) is operated at high speed. Therefore, the time required for the bottom of the work implement (7) to rise to a height at which the bottom of the work implement (7) does not contact the ground is shortened, and the vehicle can be quickly switched to reverse travel, thereby improving work efficiency.

According to the second aspect of the present invention , the work implement (7) can be raised in a shorter time than in the prior art during backward traveling while eliminating the waiting time in the traveling stop state. That is, when the travel operation lever (10) is operated to a position before the maximum speed position, the engine speed increases to a peak value, and when the travel operation lever (10) is operated to the maximum speed position, the engine rotation speed increases. By adopting the control configuration in which the number is reduced, it is possible to prevent the traveling speed from being excessively increased when the vehicle travels backward at a high speed, so that the operator can easily operate the traveling vehicle body (2) in the backward direction, and the working efficiency is improved.
Moreover, since the operating speed at which the engine speed increases to the peak value is provided, the ascending speed of the link mechanism (8) increases, so that the work machine (7) attached to the link mechanism (8) contacts the ground. Since this can be prevented, the working machine (7) is prevented from being damaged, and the durability of the working machine (7) is improved.
Further, in a state in which the travel operation lever (10) is in the reverse travel stop position or the reverse travel range, the lever position detection unit (150) indicates that the operation position of the auxiliary transmission operation lever (140) is, for example, a road travel mode. If detected, the engine speed is changed to another speed control characteristic (see the engine speed control characteristic indicated by the one-dot chain line in FIG. 5A) that matches the operation stage of the travel operation lever (10). By adopting the control configuration, it is possible to prevent an unnecessary increase in the engine speed, to reduce the fuel consumption, and to prevent an unnecessary load from being applied to the components. Improves durability.
Further, according to the control characteristic of the other rotational speed described above, it is possible to prevent the reverse traveling speed from being suddenly increased, the operator can concentrate on the operation of the traveling vehicle body (2), and the operability is improved. .

According to the third aspect of the present invention , the work implement (7) can be raised in a shorter time than in the prior art while traveling backward while making the standby time in the travel stop state unnecessary. That is, when the travel operation lever (10) is operated to a position before the maximum speed position, the engine speed increases to a peak value, and when the travel operation lever (10) is operated to the maximum speed position, the engine rotation speed increases. By adopting the control configuration in which the number is reduced, it is possible to prevent the traveling speed from being excessively increased when the vehicle travels backward at a high speed, so that the operator can easily operate the traveling vehicle body (2) in the backward direction, and the working efficiency is improved.
Moreover, since the operating speed at which the engine speed increases to the peak value is provided, the ascending speed of the link mechanism (8) increases, so that the work machine (7) attached to the link mechanism (8) contacts the ground. Since this can be prevented, the working machine (7) is prevented from being damaged, and the durability of the working machine (7) is improved.
In addition, when high torque is required for reverse travel, it is possible to secure higher travel torque than usual without significantly increasing the travel speed at the start of reverse travel. In addition, it is possible to prevent the running from stopping due to insufficient torque, and the work efficiency is improved.

According to the present invention described in claim 4 , in addition to the effect of the present invention described in any one of claims 1 to 3 , the reverse speed detected by the speed detector (120) reaches the set speed. Then, by adopting a control configuration in which the engine speed is changed to maintain the set speed, it is possible to prevent the vehicle from traveling backward faster than the speed intended by the operator. Focus on the operation.
Further, since the engine speed increases until the set speed is reached, the ascent speed of the link mechanism (8) increases, so that the work machine (7) attached to the link mechanism (8) comes into contact with the ground. Since it can prevent, it is prevented that a working machine (7) breaks etc., and durability of a working machine (7) improves.

According to the fifth aspect of the present invention, in addition to the effect of the present invention according to the first, second, or third aspect, the traveling speed is higher than the engine speed at the reverse stop position of the traveling operation lever (10). Since the control lever (10) has a control configuration that lowers the minimum engine speed when in the reverse travel region, the link mechanism (8) can be raised at a high speed at the reverse stop position. The time required for the bottom of (7) to rise to a height at which the bottom does not contact the ground is shortened and can be quickly switched to reverse travel, thereby improving work efficiency.
Further, since a sudden start is prevented when the reverse operation is started, the operator can concentrate on the operation of the traveling vehicle body (2), and the operability is improved.

Moreover, according to this invention of Claim 6 , in addition to the effect of this invention of any one of Claim 1 to 5, when an operator operates a rotation speed operation part (13), The engine speed can be increased to a peak value (for example, the fourth speed in FIG. 5 (a) or a higher speed than the fourth speed although not shown). When it is necessary to increase the engine speed sometimes, the required engine speed can be secured preferentially only by operating the speed operation section (13), so that operability and work efficiency are improved.

According to the seventh aspect of the present invention, in addition to the effect of the present invention according to any one of the first to sixth aspects, the control unit (200) has a plurality of controls for controlling the engine speed. By setting the mode, it is possible to work at an engine speed that matches the operator's intentions and working conditions. Therefore, working at low output can improve fuel efficiency and work at high output. As a result, efficient work can be performed even in uneven and inclined fields.

  In addition, during reverse travel, regardless of the set control mode, priority is given to engine rotation control during reverse travel, so that even if a malfunction occurs in the electrical system, it is possible to prevent a shortage of engine speed. The vehicle body (2) and the work machine (7) are prevented from stopping, and the work efficiency is improved.

  On the other hand, since the engine can be prevented from rotating excessively, the reverse speed is prevented from suddenly increasing, the operability of the traveling vehicle body (2) is improved, and fuel is not consumed excessively. This improves fuel economy.

Side view of a 6-row riding rice transplanter that is an example of a seedling transplanting vehicle in Embodiment 1 of the present invention The top view of the 6 type | mold riding rice transplanter which is an example of the seedling transplanting work vehicle in Embodiment 1 of this invention The block diagram which shows the control system of the riding rice transplanter in Embodiment 1 of this invention The flowchart for demonstrating operation | movement of the control system of the riding rice transplanter in Embodiment 1 of this invention (A) Schematic showing the relationship between the operating position of the travel operation lever and the engine speed according to the predetermined opening of the engine throttle in the riding rice transplanter control system of Embodiment 1 of the present invention. The schematic diagram which shows the relationship between the operation position of a travel control lever, and the vehicle speed of the body shown corresponding to FIG. Schematic sectional view of a double cam storage box in the control system for a riding rice transplanter according to Embodiment 1 of the present invention. (A) The schematic plan view which shows the external shape of the 1st cam member in the control system of the riding rice transplanter of Embodiment 1 of this invention, (b) The 2nd in the control system of the riding rice transplanter of Embodiment 1 of this invention. Schematic plan view showing the outer shape of the cam member The characteristic diagram which shows the low fuel consumption mode L, the standard mode M, and the high output mode H in the control system of the riding rice transplanter of Embodiment 1 of this invention Schematic sectional view showing a modification of the double cam storage box in the control system for the riding rice transplanter according to Embodiment 1 of the present invention. (A) The schematic which looked at the riding rice transplanter of this Embodiment from the front side, (b) The enlarged view of the periphery of the bowl-shaped hole part shown to Fig.10 (a), and its periphery The block diagram which shows the control system of the riding rice transplanter shown in FIG.

  Hereinafter, the configuration and operation of a seedling transplanting work vehicle according to an embodiment of the work vehicle of the present invention will be described with reference to the drawings.

(Embodiment 1)
FIG. 1 is a side view of a six-row riding rice transplanter as an example of the seedling transplanting work vehicle of the present invention, and FIG. 2 is a plan view thereof. Moreover, FIG. 3 is a block diagram for demonstrating the control processing mechanism of the riding rice transplanter of this Embodiment.

  I. First, the configuration of the riding rice transplanter 1 according to the present embodiment will be mainly described with reference to these drawings.

  As shown in FIGS. 1 and 2, a six-row riding rice transplanter 1 that is an example of a seedling transplanting vehicle supports front and rear wheels 3 that support a body 2 (corresponding to an example of a traveling vehicle body of the present invention) so as to be able to travel on a field. , 4, a transmission 5 that shifts transmission power to the front and rear wheels 3, 4, an engine 6 that is a driving unit that supplies power to each device including the transmission 5, and a rear part of the machine body that can be raised and lowered The seedling transplanting device 7 for planting seedlings in the field by the branching power from the transmission 5, the link mechanism 8 for connecting the seedling transplanting device 7 to the rear part of the machine body, and the hydraulic lifting for moving the seedling transplanting device 7 up and down It comprises a cylinder 9, a travel control lever 10 for switching the speed change device to operate the travel speed, an operating tool for operating various devices, a control unit 12 having a steering handle 11 and the like.

  The transmission 5 includes a hydrostatic continuously variable transmission, abbreviated as HST, and an angle of a trunnion shaft (not shown) by motor electric operation that performs forward / reverse switching and continuously variable transmission linked to the operation of the travel operation lever 10. By adjusting, the engine power received by the transmission of the belt 5a is transmitted to the front and rear wheels 3 and 4 so as to be able to shift from the stop speed to the maximum speed for each of the medium-low speed range traveling and the high-speed range traveling. To do.

  The engine 6 is configured to be able to cover the driving power in the power characteristic range in various modes of the reverse driving mode, the low fuel consumption driving mode, the standard driving mode, and the high output driving mode by motor electric adjustment of the throttle opening. Drives auxiliary machinery such as a hydraulic pump for driving.

  The seedling transplanting device 7 is driven up and down by hydraulic power and is horizontally supported by adjusting the rolling angle, and is configured to be able to plant by the branching power from the transmission 5 in conjunction with the vehicle speed. In this example, the seedling planting device 7 has a six-row planting structure, a seedling mounting tank 14 on which a mat-like seedling with soil is placed on a seedling mounting surface divided into a number of planting strips, The planting device 15 includes planting devices 15 for planting seedlings on a seedling tank in the field, and a float 16 that slides on the field scene to level the ground.

  Next, a control system for controlling each device according to the conditions provided in the riding rice transplanter 1 according to the present embodiment will be described with reference to FIG.

  Here, FIG. 3 is a block diagram showing a control system of the riding rice transplanter 1 of the present embodiment.

  As shown in FIG. 3, the control system of the present embodiment includes a hydraulic lift control valve (not shown) and a hydraulic lift for raising and lowering the transmission 5, the engine throttle 20, the seedling transplanting device 7, and the seedling transplanting device 7. The elevating device 30 including the cylinder 9 is configured to be controllable by the control device 200.

  Further, as shown in FIG. 3, on the input side to the control unit 200, the traveling operation lever 10 for shifting operation of the transmission 5 and the traveling operation lever 10 are in the reverse stop position and in the reverse travel region. The reverse position detection unit 110 that detects both of the above, the speed detection unit 120 that detects the traveling speed of the machine body 2, the rise detection unit 130 that detects that the seedling transplanting device 7 has exceeded a predetermined height, and the operation of the riding rice transplanter 1 A sub-shift lever position detector 150 that detects the lever position of the sub-shift operation lever 140 that switches the mode to one of a work mode (for example, planting mode) and a movement mode (for example, road driving mode), and the engine speed An accelerator operation detector 160 for detecting the accelerator operation of the accelerator pedal 13 for operating the engine, a standard mode which is a power characteristic of the engine 6, a low fuel consumption mode, a high output mode, and a reverse mode Any mode selection unit 170 selects one mode and, from within, the seedling transplantation apparatus 7, start planting, drop, stop, increase, and the elevation lever 180 for switching the automatic various operations are connected.

  The movement of the travel control lever 10 is input to the control unit 200 as a detection value of a potentiometer (not shown) for detecting the forward / backward movement amount of the travel control lever 10 and a detection result by the reverse position detection unit 110. It is a configuration.

  The control unit 200 sends control signals to the transmission device 5 (HST) and the engine throttle 20 according to the detected value of the potentiometer input to the control unit 200 and the detection result of the reverse drive position detection unit 110, respectively. It is the structure which outputs.

  That is, the control unit 200 outputs a control signal for adjusting the angle of a trunnion shaft (not shown) by electric motor operation to the transmission 5 and adjusts the opening degree of the engine throttle 20. The motor for driving is used to output a control signal for controlling the rotational speed of the engine 6. A method for controlling the engine speed in this case will be described later.

  The travel control lever 10 can be positioned at each shift position in an eight-step forward operation range, a forward stop position (forward idling position), a reverse stop position (reverse idling position), and a five-step reverse travel range. It is configured (see FIG. 5A).

  II. Next, the operation of the control system of the riding rice transplanter 1 according to the present embodiment will be described with reference to FIGS. 4 and 5 mainly with respect to engine rotation control.

  Here, FIG. 4 is a flowchart for explaining the operation of the control system for the riding rice transplanter in the first embodiment of the present invention. FIG. 5 (a) in the riding rice transplanter control system according to the first embodiment of the present invention, the operation position of the travel operation lever and the engine speed according to the opening of the engine throttle determined in advance corresponding thereto. FIG. 5B is a schematic diagram showing the relationship between the operation position of the traveling operation lever and the vehicle speed of the airframe shown corresponding to FIG. 5A.

  (II-1). Here, during the seedling transplanting operation of the riding rice transplanter 1 according to the present embodiment (the seedling transplanting operation is simply referred to as planting operation), the traveling operation lever 10 moves backward when switching from forward traveling to backward traveling. Within the travel area, the travel operation lever 10 is closer to the maximum speed position than the engine speed when the engine speed is at the highest speed position where the travel speed is set to the maximum (here, the fifth position in the reverse travel area). Engine speed when the travel operation lever 10 is in the reverse stop position, and the engine speed is higher when the travel operation lever 10 is in the reverse stop position. Control that makes the number higher than the engine speed when the travel operation lever 10 is at a predetermined position in the reverse travel region (here, the first and second step positions of reverse travel in FIG. 5A) , With reference to FIG.Such engine speed control is referred to herein as “first control”.

  In the present embodiment, description will be made assuming that the lifting lever 180 has already been switched to “automatic” by the operator, and the auxiliary transmission operation lever 140 has been switched to the “planting mode”.

  As shown in FIG. 4, when the operator moves the traveling operation lever 10 from the forward stop position to the reverse stop position, the control unit 200 that has received the detection signal from the reverse position detection unit 110 (see step S101 in FIG. 4). ) Based on the detection signal from the auxiliary transmission operation lever position detection unit 150, it is determined whether or not the current operation mode is other than the “planting mode” (see step S102 in FIG. 4). Here, since the sub-shift operation lever 140 has already been switched to the “planting mode”, the process proceeds to step S103.

  On the other hand, if the current operation mode is other than “planting mode”, the execution of “first control” is terminated, and “normal control” corresponding to each operation mode is executed (see step S118 in FIG. 4). . Here, the “normal control” includes “second control” described later (refer to the engine speed control characteristic indicated by the one-dot chain line in FIG. 5A), and other than “first control”. It is a generic term for control.

  As a result, when the travel operation lever 10 is in the reverse travel stop position or the reverse travel range, the sub-transmission operation lever position detection unit 150 indicates that the operation position of the sub-transmission operation lever 140 is, for example, a road travel mode. Is detected, instead of the “first control”, the “second control” described later is executed in the normal control, thereby preventing an unnecessary increase in the engine speed. In addition, the fuel consumption can be reduced, and an excessive load is prevented from being applied to the constituent members, so that the durability of the apparatus is improved.

  Further, as shown in FIG. 5 (a), the engine speed of the “second control” is the engine speed indicated by the solid line of the “first control” (FIG. 5 (a)) except for the fifth reverse travel stage. Since the rotational speed is lower than that (see the control characteristic of the number), it is possible to prevent the reverse traveling speed from being suddenly increased, and the operator can concentrate on the operation of the airframe 2 and the operability is improved.

  Next, in step S103, first, the control unit 200 determines whether or not the seedling transplanting device 7 has exceeded a predetermined height based on the detection signal from the rise detection unit 130. Proceed to On the other hand, if the seedling transplanting device 7 exceeds a predetermined height, the control characteristic of the engine speed is set to “second control” (to be described later) (engine speed control indicated by a one-dot chain line in FIG. 5A). (See the characteristics), and the lifting / lowering operation of the seedling transplanting device 7 by the lifting / lowering device 30 is not performed (see step S119 in FIG. 4).

  Thereby, when the raising detection part 130 detects that the seedling transplanting device 7 has already risen beyond the predetermined height, the raising / lowering operation by the raising / lowering device 30 is unnecessary, and the engine speed is set to “first”. Since the control is switched from “control” to “second control”, an unnecessary increase in the engine speed can be prevented, fuel consumption can be reduced, and an extra load is applied to the components. Since this is prevented, the durability of the apparatus is improved.

Further, while the seedling transplanting device 7 is being lifted, the engine speed is set to a high speed in anticipation of the load on the engine 6 ("first control"), so that the predetermined height is reached. After the lift, the load on the engine is lightened by stopping the lifting device 30. Therefore, if the “first control” is continued as it is, the reverse travel speed of the airframe 2 may suddenly increase. Therefore, by switching to the “second control”, the reverse travel speed of the airframe 2 suddenly increases. Therefore, the operator can concentrate on the operation of the machine body 2 and the operability is improved.

  Next, in step S104, the opening of the engine throttle 20 is set to a predetermined angle in order to increase the engine speed to a predetermined value (about 2600 rpm in FIG. 5A). Thereby, the raising / lowering device 30 starts the raising of the seedling transplanting device 7.

  As a result, when the traveling operation lever 10 is in the reverse stop position, the engine speed is increased and the traveling operation lever 10 is operated to a predetermined position (here, the first step and the second step) in the reverse traveling region. In this case, the link mechanism 8 and the seedling transplanting device 7 can be raised at a high speed at the reverse stop position, and the bottom of the seedling transplanting device 7 can be It is possible to ascend in a short time to a height that does not contact the vehicle, and to quickly switch to reverse travel, improving work efficiency.

  In addition, since the engine speed is set low at least at the first stage where reverse travel is started, the aircraft 2 can be prevented from starting suddenly, and the operator can concentrate on the operation of the aircraft 2 Improves.

  Next, when the operator moves the travel operation lever 10 from the reverse stop position (reverse idling position) to the reverse travel region, the reverse position detection unit 110 detects this, and the travel control lever is moved to the reverse travel region. 10 is notified to the control unit 200 (see step S105 in FIG. 4).

  Upon receiving the above notification, the control unit 200 temporarily rotates the engine until the travel operation lever 10 moves to the fifth stage (step S106 in FIG. 4), that is, when the travel control lever 10 moves to the first stage from the stop position. While the engine throttle 20 is set to a predetermined opening degree so as to decrease the number (in FIG. 5A, it is decreased from about 2600 rpm to about 2100 rpm), and while moving from the first stage to the fourth stage, The engine throttle 20 is controlled to a predetermined opening degree so as to increase the engine speed sequentially (see step S107 in FIG. 4). On the other hand, when moving to the fifth stage, the control unit 200 is notified that the fourth stage has been exceeded by the detected value of the potentiometer (see step S106 in FIG. 4). The number of revolutions is reduced below the number of revolutions in the fourth stage (see S117 in FIG. 4 and FIG. 5A), and the process proceeds to step S108.

  In step S107, as described above, the control unit 200 sets predetermined control characteristics (see the solid line in FIG. 5A) according to the detection value from the potentiometer that detects the movement amount of the travel operation lever 10. Based on this, the engine speed is controlled (see step S107 in FIG. 4).

  Incidentally, as shown in FIG. 5 (a), the engine speed control characteristic (see the solid line in FIG. 5 (a)) indicates that the seedling transplanting device 7 has a predetermined height during reverse traveling during planting work. Engine speed (see steps S105 and S119 in FIG. 4) (see the alternate long and short dash line in FIG. 5A), and other than planting operations, for example, on the road Compared to the engine speed set for reverse running (see the one-dot chain line in FIG. 5A), it is set higher except for the fifth stage. The control based on the engine speed indicated by the one-dot chain line in FIG. 5A is referred to as “second control”.

  That is, according to the control characteristic indicated by the solid line in FIG. 5A, the reverse rotation position at the time of planting is set higher than the engine speeds of the first and second stages. Then, when moving to the first stage from the stop position, the engine speed is once reduced to a substantially normal speed. From the first stage to the fourth stage, the normal position corresponding to the position of the travel operation lever 10 is normal. If the engine speed is increased more rapidly and moved from the fourth stage to the fifth stage, the engine has a unique control characteristic in that the engine speed is reduced from that of the fourth stage. The change in vehicle speed is shown in FIG.

  FIG. 5 (a) is a schematic diagram for explaining the control characteristics of the engine speed during the planting operation of the riding rice transplanter 1 of the present embodiment, and FIG. It is the schematic which shows the vehicle speed corresponding to a). The engine speed and the vehicle speed based on the “first control” of the present embodiment are indicated by solid lines, the engine speed and the vehicle speed during reverse travel based on the “second control” are indicated by a dashed line, When traveling forward, it is indicated by a broken line.

  Thereby, the seedling transplanting device 7 can be raised more quickly than before while traveling backward without waiting at the backward traveling stop position. In addition, when the traveling operation lever 10 is operated to a position ahead (the fourth stage in FIG. 5A) rather than the last part in the backward traveling direction (the fifth stage in FIG. 5A), When the engine throttle 20 is controlled to a predetermined opening degree so that the engine speed (about 3100 rpm in FIG. 5A) increases, and the travel operation lever 10 is operated to the last part in the reverse travel direction. Since the engine throttle 20 is controlled to a predetermined opening degree so that the engine speed (about 2900 rpm in FIG. 5A) decreases, the travel operation lever 10 is moved to the rearmost side. Thus, when the vehicle travels backward, it is possible to prevent the traveling speed from being excessively increased, and the operator can easily operate the airframe 2 backward to improve the work efficiency.

  Further, by providing a position (in the present embodiment, the fourth stage) at which the engine speed increases to the peak value in the middle of the reverse travel area of the travel operation lever 10, the link mechanism and the seedling transplanting device 7 are lifted. Since the speed is increased and the seedling transplanting device 7 can be prevented from coming into contact with the heel during reverse traveling, the seedling transplanting device 7 can be prevented from being damaged and the durability can be improved.

  Here, the description returns to each step in FIG. 4 again.

  That is, in step S108, the same determination as in step S103 described above is performed. If the predetermined height is not exceeded, it is determined whether the reverse travel speed of the airframe 2 has reached the set speed (step S109 in FIG. 4). If not reached, the process proceeds to step S110.

  A change in the amount of movement of the travel control lever 10 is determined from the detected value of the potentiometer (see step S110 in FIG. 4). If there is no change, the engine speed is maintained (see step S111 in FIG. 4). The same process as step S103 is performed, and the process returns to step S110.

  On the other hand, if it is determined in step S110 that there is a change in the movement amount, the process returns to step S105 and the above operation is repeated. Here, when the traveling operation lever 10 moves in the direction toward the reverse stop position, the engine speed decreases sequentially corresponding to the position (step S107 in FIG. 4).

  If the travel control lever 10 is not detected in the reverse travel area in step S105, it is further determined whether or not the travel control lever 10 is detected in the reverse stop position (see step S113 in FIG. 4). In this case, the engine rotation control here (“first control”) ends. If detected, the process returns to step S103 to repeat the above operation.

  If it is determined in step S109 that the reverse travel speed of the airframe 2 has reached the set speed, the engine speed is controlled so that the set speed is maintained even if the travel control lever 10 is further operated to the higher speed side. However, in step S115, the same process as in step S103 described above is performed.

  The set speed can be freely selected by the operator by switching a changeover switch (not shown).

  Further, when the traveling speed of the machine body 2 is maintained at the set speed, if the operator moves the traveling operation lever 10 and determines that the moving direction is the direction toward the reverse stop position (step S116 in FIG. 4). (Refer), the process returns to step S101 by return, and the above process is repeated. If it is determined in step S116 that the direction is not toward the reverse stop position, the process returns to step S114 and the above process is repeated.

  As a result, the operator can select and set the set speed in advance with the changeover switch, and the set speed can be maintained, so that it is possible to prevent the vehicle from traveling backward at a speed faster than the speed intended by the operator, The operator can concentrate on the operation of the airframe 2.

  In addition, since the engine speed increases faster than the conventional device until the set speed is reached, the ascending speed of the link mechanism and the seedling transplanting device 7 is increased, so that the seedling transplanting device 7 becomes trapped during the reverse travel. Contact can be prevented, the seedling transplanting device 7 can be prevented from being damaged, and durability can be improved.

  In addition, when the number of planting lines is large and the weight of the seedling transplanting device 7 is increased, such as an 8-row planting planter or a 10-row planting planter, the load on the engine 6 required for raising the seedling transplanting device 7 increases. Even if the opening degree of the engine throttle 20 corresponding to the engine speed shown in FIG. 5 (a) is given, the vehicle speed becomes lower than that shown in FIG. 5 (b) by the amount required for high torque. In some cases, the vehicle speed may be similar to the conventional vehicle speed. Even in this case, since the vehicle speed during backward traveling can be maintained at the same level as in the past, it is possible to raise the seedling transplanting device 7 faster than before while traveling backward without waiting at the backward traveling stop position. Work efficiency is improved.

  (II-2). In the above description, the case where the operator operates the traveling operation lever 10 to adjust the vehicle speed of the airframe 2 has been described, but here, the operation when the operator steps on the accelerator pedal 13 during reverse traveling is further described. explain.

  When the control unit 200 performs the above-described "first control" during reverse travel, when the operator steps on the accelerator pedal 13, the control unit receives a detection signal from the accelerator operation detection unit 160. 200 performs control to increase the engine speed in preference to "first control".

  That is, the control unit 200 issues a command for further increasing the rotational speed of the engine 6 to the engine throttle 20.

  As a result, when the operator depresses the accelerator pedal 13, the engine rotational speed reaches a peak value (for example, the rotational speed at the fourth stage in FIG. 5A or a rotational speed higher than that at the fourth stage, not shown). If it is necessary to increase the engine speed during reverse travel, the required engine speed can be secured preferentially by simply depressing the accelerator pedal 13, so that the operability is improved. In addition, work efficiency is improved.

  (II-3). In the above description, the description has been made mainly on the operation at the time of reverse traveling in the field, but here, for example, an engine for securing a high torque necessary when the machine body 2 climbs the step board or exits the field. The control of the rotational speed will be described with reference to FIGS.

  FIG. 6 shows a double cam storage box 330 in which the first cam member 310 and the second cam member 320 are positioned so as to be switchable at the stop position of the travel operation lever 10 and the shift position of each step in the forward / reverse range. 7A and 7B are schematic plan views showing the outer shapes of the first cam member 310 and the second cam member 320, respectively.

  As shown in FIG. 6, a rotating shaft member 337 instructed to be freely rotatable by bearing members 337 a and 337 b is disposed inside the storage cases 330 a and 330 b that are fastened together so as to have a predetermined space inside. Has been. A transmission plate 336 is always fixed to the rotary shaft member 337 by a lock key 336a. Further, the transmission plate 336 is configured such that the movement of the forward operation, the stop operation, and the reverse operation by the travel operation lever 10 can be transmitted by the interlocking member 10a. Further, the first cam member 310 and the second cam member 320 disposed on the left side of the transmission plate 336 in the drawing are substantially fan-shaped as shown in FIGS. 7 (a) and 7 (b). A rotary shaft member 337 is rotatably inserted into through holes 312 and 322 provided at positions corresponding to the main points. The through holes 312 and 322 are respectively formed with claw recesses 311 and 321 into which claw portions 334a of a switching lock member 334 described later are inserted.

  Here, the first cam member 310 and the second cam member 320 will be described with reference to FIGS. 7 (a) and 7 (b). The first cam member 310 is a cam for realizing the operation positions of the reverse 5 stages and the forward 8 stages described in FIG. 5 in the above embodiment, and the fan-shaped arc-shaped end portion corresponds to the stop position. Position, position corresponding to 5 stages of 1st, 2nd, 3rd, 4th, 5th in the reverse travel area, and position corresponding to 8 stages in the forward travel area, respectively, are equally spaced An arcuate recess 313 is formed.

  On the other hand, unlike the first cam member 310, the second cam member 320 has a fan-shaped arc-shaped end portion at a position corresponding to the stop position and a reverse travel range of 1.5 steps, 3 steps, 4 steps. Arc-shaped recesses 323 are formed at positions corresponding to four stages of five stages and positions corresponding to eight stages in the forward travel region, but are not equally spaced. In other words, the operation position next to the stop position in the reverse travel area is 1.5 steps between the first step and the second step in terms of the relationship with the step of the first cam member 310. Subsequent operation positions are 3, 4, and 5.

  Further, at the ends of the first cam member 310 and the second cam member 320, forward / reverse switching and continuously variable transmission linked to the operation position of the travel operation lever 10 are performed according to a command from the control unit 200. ) Are provided with transmission arms 314 and 324 for transmitting the forward / backward movement amount of the traveling operation lever 10 to a potentiometer (not shown).

  Here, referring again to FIG.

  A groove 337c is formed in a part of the outer periphery of the rotating shaft member 337 along the axial direction, and the cylindrical cover 339 having an outer diameter larger than the outer diameter of the rotating shaft member 337 is formed so as to cover the groove 337c from the outer periphery. Is provided. A bar-shaped switching lock member 334 having a convex claw portion 334a formed at the tip end thereof is urged by a leaf spring member 335 in a space surrounded by the groove 337c and the cylindrical cover 339, so that the rotating shaft member 337 It is arranged to be movable in the axial direction.

  On the other hand, the double cam storage box 330 is supported by a part of the storage cases 330a and 330b so as to be slidable in the direction of the arrow A, and is arranged in parallel with the rotary shaft member 337, and one end of the storage case 330a. A switching shaft 332 protruding outside is disposed. A switching lever 331 is attached to one end of the switching shaft 332 so that the operator can easily grip it with his / her hand, and a switching lock member 334 is attached to the other end to move the switching lever 331. An interlocking plate 333 for interlocking is fixed.

  As a result, the claw portion 334a of the switching lock member 334 causes the claw recess 321 of the second cam member 320 or the first cam in conjunction with the movement of the switching lever 331 when the travel operation lever 10 is at the stop position. One of the cam members is temporarily fixed and locked to the rotating shaft member 337 by being inserted into the claw recess 311 of the member 310.

  Further, a plurality of arc-shaped recesses 313 and 323 formed in each of the first cam member 310 and the second cam member 320 are provided on the outer wall of the double cam storage box 330 in order to position the traveling operation lever 10 in association with each other. Rollers 338a1 and 338b1 are rotatably provided at the lower ends of the contact spring members 338a and 338b whose upper ends are fixed by the spring retaining pins 340. The rollers 338a1 and 338b1 are arcuate recesses formed by the contact spring members 338a and 338b in a state in which the first cam member 310 and the second cam member 320 can rotate around the axis of the rotary shaft member 337, respectively. 313 and 323 are energized.

  The arrangement of the first cam member 310 and the second cam member 320 is not limited to FIG. 6, and the first cam member 310 is arranged at a position closer to the transmission plate 336 side than the second cam member 320. May be.

  With the above configuration, for example, when the aircraft 2 climbs the step board in reverse travel, and the operator predicts that torque is likely to be insufficient, the travel operation lever 10 is in the reverse stop position, When the switching lever 331 is slid in the pushing direction, the claw portion 334a of the switching lock member 334 moves in the same direction and engages with the claw recess 321 of the second cam member 320, so that the second cam member 320 is engaged. Is fixedly locked to the rotary shaft member 337. Thereby, the switching from the first cam member 310 to the second cam member 320 can be easily and reliably performed.

  Thereafter, when the operator moves the traveling operation lever 10 to a position where the user first feels the click feeling in the reverse traveling region, the transmission plate 336 and the second cam member 320 correspond to the operation, and the rotating shaft member 337 is moved. The roller 338b1 comes into contact with the arcuate recess 323 formed at the 1.5 stage position of the second cam member 320 shown in FIG. 7B. The travel operation lever 10 is positioned in a state where it can swing in the direction.

  At this time, the controller 200 controls the engine throttle 20 with respect to the engine speed corresponding to the position between the first reverse speed and the second reverse speed shown in FIG. 5A (in FIG. 5A). And an opening degree command for obtaining an output corresponding to about 2300 rpm. Since the step board has a steep slope, the actual engine speed does not increase up to 2300 rpm, so the vehicle runs at a low speed, but a high torque is obtained instead. On the other hand, the transmission 5 (HST) receives the command from the control unit 200 and transmits the engine power to the front and rear wheels 3 by adjusting the angle of the trunnion shaft corresponding to the operation of the reverse travel of the travel operation lever 10 to 1.5 steps. By shifting the transmission to 4, a low speed and high torque output can be obtained at the start of reverse travel.

  As a result, when high torque is required for reverse traveling, it is possible to secure a higher traveling torque than usual without significantly increasing the traveling speed at the start of reverse traveling. In this case, it is possible to prevent the running from being stopped due to insufficient torque, and the work efficiency is improved.

  An example of the first lever positioning portion of the present invention corresponds to the configuration including the first cam member, the contact spring member 338a, the roller 338a1, and the like of the present embodiment, and the second lever positioning of the present invention. An example of the portion corresponds to a configuration including the second cam member, the contact spring member 338b, the roller 338b1, and the like of the present embodiment. An example of the switching unit of the present invention corresponds to a configuration including the switching lever 331, the switching shaft 332, the interlocking plate 333, the switching lock member 334, the leaf spring member 335, and the like of the present embodiment.

  (II-4). In the above description, the operation at the time of reverse traveling in the field has been mainly described. However, in this case, the control unit 200 electronically controls, for example, the timing of fuel injection to the engine 6 to reduce the standard mode and the low speed. The operation when the mode selection switch 170 is used to switch a plurality of engine control modes for controlling the engine speed such as the fuel efficiency mode, the high output mode, and the reverse mode will be described with reference to FIG.

  Here, FIG. 8 is a characteristic diagram showing the low fuel consumption mode L, the standard mode M, and the high output mode H in the control system for the riding rice transplanter according to the first embodiment of the present invention.

  Hereinafter, control of each device in an engine control system that operates a plurality of engine control modes will be described.

  As shown in FIG. 8, in the engine control system here, as the power characteristics in the forward traveling of the engine 6, the rotational speed by the vehicle speed instruction from the forward stop position of the traveling operation lever 10 to the highest speed position in eight stages is low. A fuel consumption mode L, a standard mode M, and a high output mode H are set.

  Here, the low fuel consumption mode L is a power characteristic starting from low rotation idling L0 for low fuel consumption driving, and the standard mode M is a power characteristic starting from normal rotation idling M0 for normal driving, and the high output mode H Is a power characteristic starting from a high rotation idling H0 for use in running through a slack. The reverse mode is a control mode set for reverse travel including the above-described “first control” (see FIG. 5).

  The control unit 200 is configured so that one of the four rotation modes can be selected by the mode selection switch 170, and the instruction from the travel operation lever 10 starts from the forward stop position “0 stage” as shown in FIG. The high output mode H is applied to the low speed range up to the lever position “2nd stage” immediately after, and the rotation mode selected by the mode selection switch 170 is applied to the middle speed range or higher of the lever position “3rd stage” or higher.

  For example, when the fuel efficiency mode L is selected by the mode selection switch 170, the engine power is supplied to the transmission 5 by the characteristic lines connecting the points H0, H2, L3, and L8 on the characteristic diagram shown in FIG. To do. In the control operation based on such power characteristics, when the traveling control lever 10 is operated to increase the speed from the forward stop position “0 stage”, the transmission 5 is stopped at a low speed immediately after the start from the idling rotation H0 in the high output mode H. The high output mode H is maintained up to the lever position “2 stage” in the range, and then the mode selection switch 170 shifts to the low fuel consumption mode L by the speed increasing operation in the medium speed range.

  On the other hand, when the reverse mode is selected by the mode selection switch 170, the control mode set for the reverse travel including the “first control” (see FIG. 5) described above is performed.

  Further, for example, even when the low fuel consumption mode L is selected by the mode selection switch 170, when the operator operates the travel operation lever 10 to the reverse stop position and the reverse travel range, the mode selection switch 170 is selected. Regardless of the selection result, the engine speed is controlled based on the reverse mode.

  As described above, when the planting operation traveling is performed by the transmission device 5 and the seedling transplanting device 7 by supplying power from the engine 6 to each device with a power characteristic range extending from the low fuel consumption traveling to the sluggish traveling, the low fuel consumption mode L, the standard The engine is controlled according to the operation of the travel control lever 10 in accordance with the mode selection of either mode M or high output mode H, and the high output mode H is applied only when the vehicle stops and travels in the low speed range immediately after starting. Is done.

  Also, during reverse travel, the engine speed based on the reverse mode is prioritized regardless of the selection result of the mode selection switch 170, so there is no need to finely control the fuel injection timing by electronic control. It is possible to prevent the engine speed from being uncontrollable and insufficient from being caused by the abnormality of the electric system concerned, and it is possible to prevent the traveling vehicle body and the seedling transplanting device 7 from being stopped, thereby improving the work efficiency.

  The low fuel consumption mode L can improve fuel consumption and reduce exhaust gas in the case of hard soil, and the high output mode H can stabilize the low-speed driving posture and raise and lower the planting part in the case of soil with severe mud. Ensuring sufficient hydraulic pressure necessary to improve the work efficiency and seedling planting accuracy makes it possible to control the engine according to the soil condition by simple operation by selecting the mode, and stop Since the high output mode H is applied only when traveling at low speeds immediately after starting and when starting, even if a non-conforming rotation mode is selected in the case of soil with severe muddy, It is possible to improve fuel efficiency and reduce exhaust gas during driving.

  In the embodiment described above, as the first control, as shown in FIG. 5 (a), the engine speed when the traveling operation lever 10 is in the reverse stop position is set, and the traveling operation lever 10 moves backward. The control for making the engine speed higher than the engine speed when it is at a predetermined position in the travel area (the first and second positions of the reverse travel in FIG. 5A) has been described. The traveling operation lever 10 has the highest speed compared to the engine speed when 10 is in the highest speed position (for example, the fifth stage position in the reverse traveling area) where the traveling speed is set to the highest in the backward traveling area. The engine in the case where the travel operation lever 10 is in the reverse stop position only needs to be a control for increasing the engine speed when it is in a position before the position (for example, the fourth position in the reverse travel region). The number of revolutions can be adjusted with the travel lever 10 Predetermined position of the reverse running range (e.g., FIG. 5 (first and second stages of the position of the reverse running of a)) may be controlled to be lower than the engine speed when it is in.

  Even in this case, since the engine speed in the reverse travel region increases more rapidly than in the past, the working machine such as the seedling transplanting device 7 can be increased more quickly while eliminating the waiting time in the travel stop state. .

  In the above embodiment, as shown in FIG. 5 (a), the engine speed at the reverse stop position is controlled to a value higher than the first reverse speed and the second speed and lower than the third speed to the fifth speed. However, the present invention is not limited to this. For example, the engine speed is controlled to the same high speed (for example, full throttle) as the four-stage speed shown in FIG. good. As a result, the seedling transplanting device 7 quickly rises at the reverse stop position, so that mud is clogged in a grooving device (not shown) provided at the fertilizer fertilizer outlet of the seedling transplanting device 7 for cutting a groove in the field. Can be prevented. In addition, if the grooving device is close to the farm scene during reverse travel, mud is clogged, filling the fertilizer outlet, and work efficiency is reduced. Further, the engine speed may be controlled when the traveling operation lever 10 is in the reverse stop position and the elevating lever 180 is switched to the “up” position.

  In the above embodiment, the configuration has been described in which the engine speed is controlled to the same high speed (for example, full throttle) as the four-stage speed shown in FIG. 5A at the reverse stop position. For example, if the seedling transplanting device 7 is lowered to the point where the float 16 (see FIG. 1) contacts, mud enters the grooving device if the reverse speed is high even if the seedling transplanting device 7 is raised at a high speed. Since there is a possibility, for example, while the idling rotational speed at the stop position is maintained, the seedling transplanting device 7 is slowly raised while slowly moving backward at a very low speed until the float 16 is not grounded. If it is detected that the engine has risen to some extent, a configuration may be adopted in which the engine speed is switched to the same high rotation speed (for example, full throttle) as the four-stage rotation speed shown in FIG. Thereby, even when the seedling transplanting device 7 is lowered to the point where the float 16 (see FIG. 1) is grounded, mud does not easily enter the grooving device, and the seedling transplanting device 7 can be quickly raised. .

  The float 16 is provided with a potentiometer (not shown) for detecting the inclination of the float 16, and the control device 200 determines whether the float 16 is in contact with the field scene based on the detection angle of the potentiometer. The configuration.

  Further, when the seedling transplanting device 7 is raised to a predetermined height or higher and the backlift switch that constitutes the rising detection unit 130 is pressed, the operator manually operates the lifting lever 180 to set the “lifting” position. The engine speed is controlled so as to maintain the engine speed at the speed corresponding to the current operation stage of the travel control lever 10 (see the engine speed indicated by the one-dot chain line in FIG. 5A). To do.

  In the above embodiment, since the engine speed does not change even if the raising / lowering lever 180 is mistakenly moved to the “up” position with the seedling transplanting device 7 raised, the consumption of excess fuel is reduced. It is suppressed and fuel efficiency is reduced.

  Further, in the above embodiment, the case where the engine speed is controlled mainly by the opening degree of the engine throttle 20 has been described. However, the present invention is not limited to this. For example, the engine speed can be finely adjusted by electronic control. A configuration using a type of engine (for example, a DFi engine) that switches between them may be used.

  Further, in the above embodiment, the travel operation lever 10 is located at a position one step before the highest speed position from the engine speed at the highest speed position in the reverse travel range (see FIG. 5A). Although the configuration (see FIG. 5A) for increasing the engine speed in the reverse fourth stage) has been described, the present invention is not limited to this, for example, a position two steps before the highest speed position ( For example, a position that corresponds to the third reverse stage in FIG. 5A) or a position that is three steps before (for example, corresponds to the second reverse stage in FIG. 5A) may be set. Even in this case, the same effect as described above is exhibited.

  In the above embodiment, the case has been described in which the forward travel can be switched to 8 steps and the reverse travel can be switched to 5 steps. However, the present invention is limited to the number of steps that can be switched between forward travel and reverse travel. It goes without saying that there is nothing.

  Moreover, although the case where all the components shown in FIG. 3 were provided was demonstrated in the said embodiment, it is not restricted to this, For example, the speed detection part 120, the raise detection part 130, the auxiliary transmission operation lever 140, the auxiliary transmission lever The position detector 150, the accelerator pedal 13, the accelerator operation detector 160, and the mode selection switch 170 may not be all or part of them. That is, a work vehicle including at least the transmission 5 (HST), the travel operation lever 10, the engine throttle 20, the engine 6, the reverse drive position detection unit 110, the lifting device 30, and the control unit 200 described above. As long as it is configured as described above, as described above, it is possible to raise the work implement in a shorter time than in the prior art during backward traveling, while eliminating the standby time in the traveling stop state.

  Moreover, although the said embodiment demonstrated the case where the angle adjustment of the trunnion shaft (illustration omitted) of the transmission 5 was performed by driving a motor (illustration omitted) by the command from the control part 200, it is not restricted to this. For example, as shown in FIG. 9, a configuration in which the movement of the traveling operation lever 10 is structurally interlocked with the trunnion shaft of the transmission 5 without using a motor by the relay link mechanism 350 may be employed. As an example of the relay link mechanism 350, in FIG. 9, a first connection wire 351 connected to the transmission arm 314 of the first cam member 310, and a second connection wire 352 connected to the transmission arm 324 of the second cam member 320 However, it shows a structure in which the relay member 353 is combined into one and further connected to the transmission 5 from there.

  In this case, the movement of the travel operation lever 10 is transmitted to the trunnion shaft of the transmission 5 by the relay link mechanism 350 and a potentiometer (not shown) for detecting the forward / backward movement amount of the travel operation lever 10. The detected value and the detection result by the reverse position detection unit 110 are input to the control unit 200, and a command for adjusting the opening of the engine throttle 20 is output from the control unit 200. Even in this case, as described above, there is an effect that the working machine can be raised in a shorter time than in the prior art during backward traveling while eliminating the standby time in the traveling stop state.

  In the above-described embodiment, the case where the reverse position detection unit 110 is provided has been described. However, the present invention is not limited to this. For example, a potentiometer that detects the movement of the traveling operation lever 10 is not only a moving amount of the traveling operation lever 10. The positive voltage output and the negative voltage according to the moving direction (forward side and reverse side) from the stop position of the travel operation lever 10 as to whether at least the travel operation lever 10 is in the reverse travel region or the forward travel region. A configuration without the reverse position detection unit 110 may be realized by making the configuration distinguishable by the output of. Even in this case, as described above, there is an effect that the working machine can be raised in a shorter time than in the prior art during backward traveling while eliminating the standby time in the traveling stop state.

  In the above-described embodiment, the first cam member 310 and the second cam member are used for controlling the engine speed for ensuring the high torque required when the machine body 2 climbs the step board or leaves the field. Although the structure which switches 320 was demonstrated, it is not restricted to this, For example, by providing the rear-wheel rotation sensor 4a (refer FIG. 11) which detects the rotation speed of the rear-wheel 4, the driving | running | working operation lever 10 is made into the 1st step | paragraph of reverse travel. When operating the climbing board (see FIGS. 5 (a) and 7 (a)), the control unit 200 allows the rear wheel rotation sensor to safely climb the predetermined speed (for example, the walking board). It is good also as a control structure which raises an engine speed until it detects a rotation speed of a grade). As a result, even when high torque is required, the engine speed does not increase excessively, and the operator can concentrate on the operation of the airframe 2 and the operability is improved.

  By the way, the work vehicle in which the work machine such as the seedling transplanting device 7 can be mounted on the rear part of the traveling vehicle body is used for the operator to get off the driver's seat and perform the work in traveling over the heel and loading / unloading on the truck, It is difficult to change the speed of the work vehicle. As a configuration for solving this, as shown in FIG. 1, a front arm 42 is provided on the front side of the riding rice transplanter 1 that is an example of a work vehicle so as to be able to switch in and out. That is, the operator can manually tilt the front arm 42 to the front side of the bonnet 40 (see arrow F in FIG. 1). Hereinafter, the configuration and operation of the front arm 42 will be described with reference to FIGS. 10 (a), 10 (b), and 11.

  Here, Fig.10 (a) is the figure which looked at the riding rice transplanter 1 of this Embodiment from the front side, FIG.10 (b) is the saddle-shaped hole part 41 shown to Fig.10 (a), and its FIG. 11 is a block diagram showing a control system of the riding rice transplanter 1 shown in FIGS. 10 (a) and 10 (b). The same components as those shown in FIG. 3 are denoted by the same reference numerals, and the description thereof is omitted.

  As shown in FIG. 10, at the lower part of the bonnet 40 provided at the front part of the machine body 2 and at the substantially central part in the left-right direction, a long hole 41a that is long in the vertical direction and narrow on the lower side, and a round hole that is wider in the left-right direction than the long hole 41a A bowl-shaped hole 41 made of 41 b is formed, and the base of the front arm 42 is arranged inside the hole 41. A restricting plate 43 is provided on the side portion 42a of the base portion of the front arm 42 and inside the bonnet 40, and a spring 44 for urging the restricting plate 43 toward the front arm 42 is provided.

  The front arm 42 is configured to have substantially the same diameter as the width 41aw of the lower end portion of the long hole 41a, and the operator manually pushes the front arm 42 in the direction opposite to the urging direction of the spring 44 to regulate the front arm 42. If the plate 43 is not moved in the lateral direction (leftward in FIG. 10B), the plate 43 cannot move to the round hole 41b and can be rotated in the front-rear direction by less than about 10 degrees.

  In addition, the front arm 42 is provided with a front potentiometer 45 (see FIG. 11) for detecting a rotation operation angle (a rotation angle in the direction of arrow F in FIG. 1), and the potentiometer 45 and the control device 200 are connected to each other. When the rotation operation angle of the arm 42 is equal to or greater than a certain angle (30 to 60 degrees) and the operation stage of the traveling operation lever 10 is the first reverse stage, the rotational speed of the engine 6 is increased via the engine throttle 20. It is set as the structure made to do.

  When the rear wheel rotation sensor 4a detects the start of rotation of the rear wheel 4 (the rear wheel rotates 1/4 to 1), the engine speed at the time of detection is held until the travel operation lever 10 is operated. The configuration.

  With the above configuration, when the vehicle climbs back on an inclined land such as a step board or a farm entrance / exit, a torque that enables the rear wheel 4 to rotate can be secured without operating the travel operation lever 10 to the second or higher step. Since the engine speed can be increased, the reverse speed can be increased without traveling backward, and the vehicle can travel backward on a step board or an inclined ground, thereby improving work safety.

  Further, the base of the front arm 42 is provided in the pit 41 formed in the bonnet 40, and the regulation plate 43 urged by the spring 44 is provided on the side 42 a of the front arm 42. Therefore, unless the front arm 42 is pushed in the direction opposite to the direction in which the spring 44 is urged, the front arm 42 does not rotate more than a predetermined angle (30 to 60 degrees). With this configuration, when the airframe 2 vibrates due to unevenness in the field or the like, the front arm 42 can be prevented from turning freely by a predetermined angle (30 to 60 degrees), so that during planting work or on flat ground The engine rotation speed suddenly increases during traveling, preventing the seedling planting row from being disturbed and the traveling speed from rapidly increasing, thereby stabilizing the seedling planting accuracy and operability.

  In the case of the reverse operation, the traveling operation lever 10 is set to the first reverse stage so that the operator can perform the reverse operation calmly, and the engine speed is increased only when the front arm 42 is rotated by a predetermined angle or more. However, when the operator gets off the aircraft and stands in front of the aircraft to move the sloping ground, the front arm 42 can be moved even if the operation step of the traveling operation lever 10 is in the second or third step. When it is tilted, if the engine speed is increased until the rear wheel rotation sensor 4a detects the forward movement of the airframe, the operator can increase the engine speed without operating the traveling operation lever 10 on the airframe. As a result, work efficiency is improved.

  However, if the operation stage of the travel control lever 10 is four or more stages, the engine speed increases and the torque that can climb the slope is ensured, and at the same time, the aircraft starts traveling at high speed, and the operator's deceleration operation is not in time, and the wall Therefore, the engine speed should not be increased even if the front arm 42 is rotated.

  Further, when the front potentiometer 45 detects a turning operation of a predetermined angle or more, a signal is sent from the control device 200 to cut off the oil feeding from the hydraulic valve 46 to the power steering mechanism (power steering cylinder) 47, The operation of the steering handle 11 may not be assisted by hydraulic pressure (see FIG. 11).

  With the above configuration, the slope where the aircraft is moved is muddy, and even if the steering handle 11 is arbitrarily operated by muddyness, the steering handle 11 hardly moves when the power steering mechanism 47 is stopped. The straight movement of the aircraft is not hindered and operability is improved.

  Further, an angular velocity sensor 48 may be provided on the front arm 42, and the engine 6 may be forcibly stopped when the angular velocity sensor 48 reacts, or the engine speed may be forcibly reduced.

  With the above configuration, when the front arm 42 is rotated, such as a step board or an inclined ground, when an operator slides his / her foot or excessively approaches a wall or the like, the front arm 42 is operated at a high speed. Since the vehicle can be stopped on the spot, safety is improved.

  A center mascot 49 is provided at the upper end of the front arm 42, which is used as a guide when the operator goes straight ahead.

  Further, the front arm 42 described with reference to FIGS. 10 and 11 and related components (front potentiometer 45, hydraulic valve 46, power steering mechanism 47, angular velocity sensor 48, etc.) are shown in FIGS. It is not limited to the case where it is provided in the riding rice transplanter 1 according to the embodiment of the present invention described using the above. For example, a configuration provided in a conventional riding rice transplanter may be used. Even in this case, the same effect as described with reference to FIGS. 10 and 11 is exhibited.

  Moreover, although the said embodiment demonstrated the case where a seedling transplanting apparatus was connected as a working machine, not only this but the structure which connects various working apparatuses other than a seedling transplanting apparatus may be sufficient.

  The work vehicle according to the present invention has an effect that the work machine can be lifted in a shorter time than the conventional one during reverse running while eliminating the waiting time in the traveling stop state, and the work vehicle such as a seedling transplanter is installed at the rear part of the vehicle body. It is useful as a work vehicle or the like that performs various operations by connecting machines.

DESCRIPTION OF SYMBOLS 1 Passenger rice transplanter 2 Body 3 Front wheel 4 Rear wheel 5 Transmission 6 Engine 7 Seedling transplanter 8 Link mechanism 9 Hydraulic lift cylinder 10 Traveling operation lever 11 Steering handle 12 Steering part 13 Accelerator pedal 14 Seedling tank 15 Planting device 16 Float

Claims (7)

A link mechanism (8) for mounting the work implement (7) on the rear part of the traveling vehicle body (2);
A lifting device (30) for lifting and lowering the link mechanism (8);
An engine (6) provided on the traveling vehicle body;
A transmission (5) for shifting and outputting the power of the engine (6);
A traveling operation lever (10) for operating the traveling speed by changing the output of the transmission by switching to any one of the forward traveling region, the stop region, and the reverse traveling region;
A control unit (200) for performing a first control for controlling the engine speed when the travel operation lever (10) is at least in the reverse travel range;
In the first control, the engine speed is set to be higher than the engine speed when the travel operation lever (10) is at the highest speed position where the travel speed is set to the highest in the reverse travel range. With the control configuration to increase the engine speed when in the front position,
A rise detector (130) for detecting that the work implement (7) exceeds a predetermined height;
The control unit (200) performs the first control until the rise detection unit (130) detects the rise of the work implement (7), and the rise detection unit (130) performs the work implement (130). 7) After detecting the rise in 7), the control structure for setting the maximum engine speed when the travel operation lever (10) is in the highest speed position where the travel speed is set to the maximum in the reverse travel range. A working vehicle characterized by that. A link mechanism (8) for mounting the work implement (7) on the rear part of the traveling vehicle body (2);
A lifting device (30) for lifting and lowering the link mechanism (8);
An engine (6) provided on the traveling vehicle body;
A transmission (5) for shifting and outputting the power of the engine (6);
A traveling operation lever (10) for operating the traveling speed by changing the output of the transmission by switching to any one of the forward traveling region, the stop region, and the reverse traveling region;
A control unit (200) for performing a first control for controlling the engine speed when the travel operation lever (10) is at least in the reverse travel range;
In the first control, the engine speed is set to be higher than the engine speed when the travel operation lever (10) is at the highest speed position where the travel speed is set to the highest in the reverse travel range. With the control configuration to increase the engine speed when in the front position,
A sub-shift operation lever (140) for switching the operation of the work vehicle to at least one of a plurality of modes including a planting mode and a movement mode;
A lever position detection unit (150) for detecting an operation position of the auxiliary transmission operation lever (140);
When it is detected that the operation position is other than the planting mode, the control unit (200) does not perform the first control, and the travel operation lever (10) is within the reverse travel range, A work vehicle having a configuration in which the engine speed is controlled to be the highest when the travel speed is at a maximum speed position where the travel speed is set to a maximum. A link mechanism (8) for mounting the work implement (7) on the rear part of the traveling vehicle body (2);
A lifting device (30) for lifting and lowering the link mechanism (8);
An engine (6) provided on the traveling vehicle body;
A transmission (5) for shifting and outputting the power of the engine (6);
A traveling operation lever (10) for operating the traveling speed by changing the output of the transmission by switching to any one of the forward traveling region, the stop region, and the reverse traveling region;
A control unit (200) for performing a first control for controlling the engine speed when the travel operation lever (10) is at least in the reverse travel range;
In the first control, the engine speed is set to be higher than the engine speed when the travel operation lever (10) is at the highest speed position where the travel speed is set to the highest in the reverse travel range. With the control configuration to increase the engine speed when in the front position,
When the travel operation lever (10) is switched to at least one position in the reverse travel area, the travel operation lever (10) is positioned at each of a plurality of switching positions corresponding to the first switching pattern. Lever positioning portions (310, 338a, 338a1),
When the travel operation lever (10) is switched to at least one position in the reverse travel area, the travel operation lever is moved at each of a plurality of switching positions corresponding to a second switching pattern different from the first switching pattern. A second lever positioning part (320, 338b, 338b1) for positioning;
The movement of the travel operation lever (10) is selectively transmitted to one of the first lever positioning part (310, 338a, 338a1) and the second lever positioning part (320, 338b, 338b1). Switching units (331, 332, 333, 334, 335) for
The position of the first stage of the reverse travel area of the second lever positioning portion (320, 338b, 338b1) is the first position of the reverse travel area of the first lever positioning portion (310, 338a, 338a1). A work vehicle characterized in that the position is between the stage and the second stage. A speed detector (120) for detecting the travel speed;
The In no event travel operation lever (10) is in said reverse travel range, when the traveling speed is detected by the speed detecting unit that has reached a predetermined speed (120), wherein the control unit (200), the travel operation lever (10) be operated further to the highest speed position direction, one of claims 1 to 3, characterized in that the arrangement for controlling the engine speed so as to maintain said predetermined velocity The work vehicle according to claim 1. When the travel operation lever (10) is operated to the reverse stop position on the reverse travel region side in the stop region, the work machine (7) is raised.
The control unit (200) determines the engine speed when the travel operation lever (10) is in the reverse stop position, and the minimum value when the travel operation lever (10) is in the reverse travel range. The work vehicle according to claim 1, 2, or 3, wherein the control configuration is set to be higher than the engine speed. A rotation speed operation unit (13) for increasing or decreasing the engine rotation speed;
The controller (200) is configured to increase the engine speed in preference to the first control when there is an operation to increase the engine speed by the speed operation section (13). The work vehicle according to any one of claims 1 to 5 , characterized in that: Mode selection for selecting any one of a plurality of control modes including at least a standard mode, a low fuel consumption mode, a high output mode, and a reverse mode capable of controlling the rotation of the engine (6) with different power characteristics. Part (170),
When the travel operation lever (10) is in the reverse travel range, the control unit (200) controls the engine speed based on the reverse mode regardless of the selection result of the mode selection unit (170). working vehicle according to any one of claims 1 to 6, characterized in that it has a configuration of controlling.

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