JP5418766B2 - Combine - Google Patents

Description

  The present invention relates to a combine.

  Conventionally, a reaping device is provided in front of a traveling device capable of continuously changing the traveling speed by a hydrostatic continuously variable transmission for traveling, and a threshing device is provided above the traveling device. A configuration in which gear shifting driving is performed by a hydrostatic continuously variable transmission for cutting and conveying in synchronization with the speed is known (see Patent Document 1).

JP2008-35737

In the above-mentioned known example, the mowing device is simply driven by the hydrostatic continuously variable transmission for mowing and transporting in synchronism with the traveling speed. Therefore, in the mowing operation at low speed, the control accuracy varies depending on the load and the characteristics of the hydraulic mechanism. Arises, and there is a problem that the transmission rotation to the cutting device stops.
In addition, if the output is transmitted so that the transmission rotation to the mowing device does not stop at the same time as the mowing operation at low speed, the hunting and follow-up delay (at the speed of the mowing device according to changes in vehicle speed) There is a problem that the follow-up to be changed is delayed.
The present application adopts a configuration in which the reaping device is driven by a reaping and hydrostatic continuously variable transmission for cutting and conveying that is different from the traveling hydrostatic continuously variable transmission, and the reaping device can be used at any vehicle speed between low speed and high speed. It is devised to improve the control accuracy of the transmitted rotation.

In the invention of claim 1 , the reaping device 4 is provided in front of the traveling device 3 capable of continuously changing the traveling speed by the hydrostatic continuously variable transmission device 12 for traveling, and the threshing device 2 is disposed above the traveling device 3. The reaping device 4 is driven by a hydrostatic continuously variable transmission 21 for harvesting and conveying in synchronization with the traveling speed of the traveling device 3, and the hydrostatic continuously variable transmission 21 for reaping and conveying is The controller 60 is configured to perform rotation control by means of a controller 60 that outputs a control to an electric motor that rotates the trunnion shaft of the HST motor for cutting of the hydrostatic continuously variable transmission 21 for cutting and conveying. The controller 60 has a vehicle speed lower than a predetermined traveling speed. Sometimes, a low-speed mode that intermittently outputs to the electric motor at a predetermined output cycle and output time is executed, and when the vehicle speed is higher than a predetermined traveling speed, the low-speed mode is A motor for detecting the rotational position of the output shaft of the electric motor when performing deceleration output to the hydrostatic continuously variable transmission 21 for cutting and conveying. The position sensor 63 is configured to reduce the output time of the intermittent output as it approaches a preset stop position, and during the deceleration output by the controller 60 to the hydrostatic continuously variable transmission 21 for cutting and conveying, The motor position sensor 63 is configured to stop the deceleration output when detecting that the motor position value of the rotational position of the output shaft of the electric motor has reached an acceleration side position less than a predetermined stop position from a predetermined stop position. At the start of traveling from the state, when the rotational speed of the reaping device 4 reaches a predetermined value or more at a vehicle speed less than a predetermined value, the motor position value at this time is And憶, even if the subsequent deceleration the output is a motor position that the combined where the structure is not decelerated output below the storage motor position value of the, by traveling hydrostatic continuously variable transmission 12 of the engine 22 The constant rotation is steplessly changed and transmitted to the traveling device 3 to travel, and the rotation of the reaping device 4 is shifted in synchronization with the traveling speed of the traveling device 3, and when the vehicle speed is lower than the predetermined traveling speed, the low speed mode The reaping device 4 is shifted in synchronization with the traveling speed, and when the vehicle speed is higher than the predetermined traveling speed, the reaping device 4 is shifted in synchronization with the traveling speed as a high speed mode.
In the low speed mode, the signal is output intermittently from the controller 60, and the output cycle is shortened and the output time is also shortened.
In the high-speed mode, the output cycle is intermittently longer and the output time is longer than that in the low-speed mode.
The trunnion shaft of the HST pump for cutting that stops the rotation from the hydrostatic continuously variable transmission 21 for cutting and conveying even in the range of the traveling speed that may cause the cutting apparatus 4 to be stopped by the load of the cutting device 4 The closer to the stop position, the shorter the intermittent output time.
If the motor position sensor 63 detects that the motor position sensor 63 has reached a speed increasing side position that is less than a predetermined value from the predetermined stop position during traveling and deceleration output, the deceleration output is stopped.
At the start of traveling from the airframe stop state, when the rotational speed of the reaping device 4 reaches a predetermined value or more when the vehicle speed is less than a predetermined value, the motor position value at this time is stored, and the stored motor position is stored even if the deceleration output is performed thereafter. No deceleration output below the value.
The inventions are claimed in claim 2, the control output to the conveyance hydrostatic continuously variable transmission 21 Reaper by the controller 60 automatically selects and controls the output mode based on a change in vehicle speed within a predetermined time When it is determined that the vehicle speed has changed from the speed in the range corresponding to the low speed mode to the speed in the range corresponding to the high speed mode, the high speed mode is selected, and conversely, the vehicle speed is low from the speed in the range corresponding to the high speed mode. When the speed is switched to a range corresponding to the mode, the combine is characterized in that the low-speed mode is selected and controlled , and during the cutting operation, the vehicle speed is within the target range from the low-speed mode to the high-speed mode. When the travel speed changes to the travel speed or the travel speed in the target range from the high speed mode to the low speed mode, the output mode is automatically selected and controlled based on the change in the vehicle speed within a predetermined time.
For example, when the vehicle speed is switched from the low speed mode to the high speed mode, the vehicle speed changes at an increased speed. Therefore, the high speed mode is selected and controlled.
On the contrary, when switching from the high speed mode to the low speed mode, the vehicle speed changes by deceleration, so the low speed mode is selected and controlled.
Inventions of claim 3, when performing the accelerated output to the feeding hydrostatic continuously variable transmission 21, wherein the cutting is rested for a predetermined time after output output, then the feature that it has a structure to re-outputs The speed increasing output to the hydrostatic continuously variable transmission 21 for harvesting and conveying is paused for a certain time after the output, and then output again.
The inventions of claim 4, the speed reduction output and accelerating output of the controller 60 are alternately repeated a predetermined number of times or more in the output within a predetermined time, deceleration and speed increasing output to adjust the output time to each half It is a combine that is characterized by the configuration, and if the deceleration output and the acceleration output are alternately output more than a predetermined number of times within a certain time, the subsequent deceleration or acceleration output will be halved Adjust the output time.
The inventions of claim 5, when the deceleration output and increasing speed output from the controller 60 is repeated output a predetermined number of times or more alternately within a certain time, so as to reduce the reduction or speed increase output subsequent to a predetermined time interval It is a combine that is characterized in that the output time is adjusted at the same time. When the deceleration output and the speed increase output are alternately output more than a predetermined number of times alternately within a certain time, the subsequent deceleration / speed increase output The output time is adjusted to reduce the value at regular intervals.
Configuration inventions of claim 6, the deceleration output and increasing speed output from the controller 60 when it is repeated output a predetermined number of times or more alternately within a certain time, to a certain time stop decelerating output or speed-increasing output from the controller 60 When the deceleration output and the speed increase output are alternately output more than a predetermined number of times within a predetermined time, the controller 60 stops the speed reduction / speed increase output for a predetermined time, Output starts again after a certain period of time.

In the first aspect of the invention, when the vehicle speed is lower than the predetermined traveling speed, the cutting and conveying hydrostatic continuously variable transmission 21 is rotated and output to the cutting apparatus 4 in the low speed mode, and when the vehicle speed is higher than the predetermined traveling speed, the high speed mode is selected. Can be rotated and output from the hydrostatic continuously variable transmission 21 for harvesting and conveying to the harvesting device 4, and the harvesting device 4 can be tuned to any traveling speed from low speed to high speed. The variation in control accuracy due to the characteristics of the mechanism is reduced to improve the control accuracy, the occurrence of rotation stoppage of the reaping device 4 during low-speed traveling can be prevented, the reliability of the reaping operation is improved, and the traveling speed is synchronized at high speeds. The followability can be improved and the cutting operation can be stabilized.
In addition to the above effects, intermittent output in the low-speed mode, and the output period is short and the output time is also short, so that delicate rotation control that can prevent rotation stoppage of the reaping device 4 can be performed and control accuracy is improved, Operability can be improved.
In addition to the above effect, the output cycle is longer and the output time is longer and intermittently output in the high speed mode than in the low speed mode to improve the control accuracy, thereby improving the follow-up performance of the reaping device 4 with respect to changes in the traveling speed. Therefore, the cutting operation can be performed at high speed, and the working efficiency can be improved.
In addition to the above-described effects, it is possible to improve the control accuracy of the hydrostatic continuously variable transmission 21 for cutting and conveying in the vicinity of the rotation stop of the cutting device 4 at the time of deceleration output to the hydrostatic and continuously variable transmission 21 for cutting and conveying. It is possible to avoid inadvertent stopping of the cutting device 4 and to improve the stability and reliability of the cutting operation.
In addition to the above effects, when the motor position sensor 63 detects that the motor position sensor 63 has reached a speed increasing side position less than a predetermined stop position during the deceleration output, the deceleration output is stopped. Therefore, it is possible to improve control accuracy, avoid the occurrence of a situation where the rotation of the reaping device 4 stops, and enable a speedy reaping operation.
In addition to the above effect, when the rotational speed of the reaping device 4 reaches a predetermined value or more when the vehicle speed is less than a predetermined value at the start of traveling, the motor position value at this time is stored, and the motor position is not changed even if the subsequent deceleration output is performed. The control accuracy can be improved so as not to decelerate the output below the stored motor position value. Even if the decelerating output is made, the number of rotations of the reaping device 4 can be ensured to be equal to or higher than the predetermined value, and the reaping device 4 during the decelerating output. Can be avoided.
In the invention of claim 2 , in addition to the effects of the above invention, the control mode can be appropriately selected in the vicinity of the predetermined speed for switching the control mode, and the traveling speed by the hydrostatic continuously variable transmission 21 for cutting and conveying is increased. It is possible to improve the control accuracy of the drive control of the synchronized reaping device 4 so as to prevent the occurrence of hunting and improve the follow-up performance. In particular, the operation near the predetermined speed for switching the control mode can be facilitated, and the operability is improved. Can be improved.
In the invention of claim 3 , in addition to the effect of the above invention, the response of the rotational acceleration of the hydrostatic continuously variable transmission 21 for chopping conveyance to the acceleration output is made accurate and the followability to the control signal is improved. Control accuracy can be improved, and hunting and overshoot (excessive rotation) can be prevented.
In the invention of claim 4 , in addition to the effect of the above invention, when the deceleration output and the acceleration output are repeated a predetermined number of times or more, the output time is adjusted so as to halve the deceleration and the acceleration output. Signal output to the hydrostatic continuously variable transmission 21 can be made appropriate, and hunting can be detected to suppress overshoot.
In the invention of claim 5 , in addition to the effects of the above invention, if the deceleration output and the acceleration output are repeated a predetermined number of times or more, the subsequent deceleration / acceleration output is adjusted to be smaller every fixed time, so the output time is adjusted. Operation can be suppressed.
In the invention of claim 6 , in addition to the effect of the above invention, when the deceleration output and the acceleration output are repeated a predetermined number of times or more, the deceleration / acceleration output is stopped for a certain time, so that the detection value of the sensor is stabilized. The output can be started again after waiting for hunting.

The side view of a combine. The relationship figure of the rotation speed of a cutting device and a vehicle speed. Schematic of a transmission mechanism. The hydraulic circuit diagram of a continuously variable transmission. Block Diagram. Increased output diagram in low-speed mode. Deceleration output diagram in low speed mode. Increased output diagram of high-speed mode. Deceleration output diagram in high speed mode. Explanatory drawing of the output time to the cutting HST motor stop position at the time of deceleration control. Block Diagram. FIG. Block Diagram. FIG. FIG.

An embodiment of the present invention will be described with reference to the drawings. Reference numeral 1 denotes an airframe frame, 2 denotes a threshing device provided at an upper position of the airframe frame 1, 3 denotes a traveling device provided at a lower position of the airframe frame 1, 4 is a mowing device provided in front of the machine frame 1, 5 is a Glen tank for temporarily storing grains taken out from the threshing device 2 provided on the side of the threshing device 2, 6 is a control unit, and 7 is A cereal discharger for cerealing grains in the Glen tank 5.
An example of the cutting device 4 includes a weeding body 8, a pulling device (not shown), a cutting blade 9, and a conveying device.
Reference numeral 10 denotes a cereal supply / conveyance device that supplies the cereal to the threshing chamber (not shown) of the threshing device 2, and 11 is a front supply for synchro provided on the starting end side of the cereal supply / conveyance device 10. It is a transport device.
The cereal supply transport device 10 supplies the cereals harvested by the reaping device 4 to the threshing chamber (not shown) of the threshing device 2 from the cereal supply port (not shown), and is threshed. Although it conveys until it discharges | emits from a cereal discharge port (illustration omitted), the structure which conveys the cereal harvested with the reaping apparatus 4 to the cereal supply supply apparatus 10 is arbitrary.

The grain candy supply / conveyance device 10 is constituted by a cocoon (not shown) and a conveyance / supply chain (feed chain, not shown). The pestle is attached to the upper cover of the threshing device 2 so as to be freely movable up and down, and is attached to the transport and supply chain to sandwich and convey the cereal. The conveyance supply chain is constituted by an endless chain, and is configured to move while being guided by an optional guide rail (not shown).
The traveling device 3 is configured such that the traveling speed can be changed by the traveling hydrostatic continuously variable transmission 12, and the rotation transmitted to the reaping device 4 is also shifted in synchronization with the traveling speed of the traveling device 3.
The traveling hydrostatic continuously variable transmission 12 increases / decreases in accordance with the amount of tilting operation of the main transmission lever 13 and, for example, as shown in FIG. The speed is changed by the work line A and the overturning work line B that is accelerated in a shorter time than the standard work line A.
The travel hydrostatic continuously variable transmission 12 changes the inclination of the pump swash plate 15 of the hydraulic pump 14 to change the amount of oil supplied to the hydraulic motor 16 steplessly and transmits the rotation. In addition, a motor swash plate 17 whose inclination angle can be switched in two stages is provided, and the upper limit of the traveling speed of the airframe can be switched between normal traveling and high-speed traveling (FIG. 4).
Reference numeral 19 denotes switching means (solenoid) for switching the motor swash plate 17.

In this case, even when the hydraulic motor 16 of the hydrostatic continuously variable transmission 12 for traveling is switched to high speed traveling, even when the main transmission lever 13 is operated at the highest speed, the harvesting device 4 does not harvest. The vehicle speed limit control is performed so as to limit the amount of oil fed from the hydraulic pump 14 to the hydraulic motor 16 of the traveling hydrostatic continuously variable transmission 12 so as to achieve a workable traveling speed.
That is, when the hydraulic motor 16 of the hydrostatic continuously variable transmission 12 for traveling is operated at the maximum speed while the main transmission lever 13 is operated at the highest speed and the rotation of the hydraulic pump 14 is maximized, the rotation of the hydraulic motor 16 is maximized. Even when the cutting device 4 is driven at an increased speed in synchronism with this maximum traveling speed line C, the cutting speed of the cutting blade 9 is deteriorated due to an excessive increase in traveling speed, and the weight is reduced. However, in the present application, the inclination of the pump swash plate 15 of the hydraulic pump 14 of the hydrostatic continuously variable transmission 12 for traveling under certain conditions (during cutting operation, etc.) may occur. Even when the main speed change lever 13 is operated at the highest speed, the vehicle speed limiting control is performed so that the speed limit line D is a traveling speed at which the cutting operation by the cutting device 4 is possible (FIG. 2).

Therefore, when the main speed change lever 13 is operated at the highest speed, the cutting marks of the cutting blade 9 are prevented from being deteriorated due to an excessive increase in traveling speed, and the cutting device 4 is prevented from being clogged or damaged due to an increase in the amount of dredging. In addition, it is possible to work at a higher vehicle speed than rice by harvesting light wheat.
Further, the hydrostatic continuously variable transmission 12 for traveling of the present application is configured to perform a sub-transmission function by enabling the traveling speed to be switched in two stages by a hydraulic motor 16. The auxiliary transmission mechanism is omitted.
The reaping device 4 and the synchro front supply / conveyance device 11 are shifted in synchronism with the traveling speed by a reaping and conveying hydrostatic continuously variable transmission 21 dedicated for reaping and transportation.
Thus, the synchronization with the running speed by the chopping and conveying hydrostatic continuously variable transmission 21 dedicated to the chopping and conveying is performed by driving the threshing device 2 and the cereal supply and conveying device 10 with constant driving rotation from the engine 22. While making the operation stable, the transfer to the cereal supply and transfer device 10 is made smooth and reliable.
In addition, the transmission rotation to the reaping device 4 and the synchro front supply / conveyance device 11 shifts in synchronization with the traveling speed. However, under a predetermined condition, the scouring / conveying hydrostatic continuously variable transmission 21 is reaped independently. The apparatus 4 and / or the front-side supply / conveyance device 11 for synchronization are configured to be driven.

Therefore, even during the predetermined travel speed from the state where the airframe is stopped, the mowing and transporting hydrostatic continuously variable transmission 21 can drive the mowing device 4 and the synchro front supply and transport device 11 at a sufficient number of revolutions. The reaping device 4 and the threshing device 2 can be driven stably immediately after the start, and the reaping operation and the threshing operation can be performed stably and reliably.
In addition, when the rotation of the traveling hydrostatic continuously variable transmission device 12 from the traveling hydrostatic continuously variable transmission device 12 to the traveling device 3 is stopped, the cutting and conveying hydrostatic continuously variable transmission device 21 independently drives the synchro front supply and transport device 11. In addition, hand-harvested corn can be supplied to the synchro front supply / conveyance device 11 and the culm supply / conveyance device 10 in a state where the machine travel is stopped, and the workability and operability of the cutting and threshing operations can be improved.

The structure of the rotation transmission mechanism from the engine 22 to the traveling hydrostatic continuously variable transmission 12 and the harvesting and conveying hydrostatic continuously variable transmission 21 is arbitrary. For example, 25A represents a traveling output pulley, 25B is an output pulley for cutting and threshing, 26 is an input pulley of the hydrostatic continuously variable transmission 12 for traveling, 28 is an intermediate pulley to which the rotation of the output pulley 25B for cutting and threshing is transmitted, 29 is an intermediate shaft, and 30 is an intermediate gear. , 31 is an intermediate transmission shaft, 32 is a pair of threshing transmission bevel gears, 33 is a threshing transmission shaft, 33A is an intermediate pulley for threshing, 34 is a handling cylinder, 35 is a processing cylinder, 36 is an intermediate gear for cutting, and 37 is cutting The cutting HST input shaft of the hydrostatic continuously variable transmission 21 for transfer, 38 is the cutting HST output shaft of the hydrostatic continuously variable transmission 21 for cutting transfer, 39 is the intermediate output shaft for cutting, and 40 is the output shaft for transfer synchronization. 41稈 Feeding and conveying intermediate output shaft, 41 </ b> A is a feeding and conveying pulley, 42 is tang, 43 is a drive gear of the cereal feeding and conveying device 10, 44 is a mowing threshing clutch, and 45 is a mowing intermediate output provided on the mowing intermediate output shaft 39. A pulley 46 and a cutting intermediate input pulley 47 and a belt 47 are wound around the cutting intermediate output pulley 45 and the cutting intermediate input pulley 46.
Reference numeral 50 denotes a gear case provided with a cutting intermediate gear 36, a cutting intermediate output shaft 39, and the like, and a cutting and conveying hydrostatic continuously variable transmission 21 is provided on the control unit 6 side of the gear case 50.
Reference numeral 51 denotes a cutting HST pump of the cutting and conveying hydrostatic continuously variable transmission 21, and reference numeral 52 denotes a cutting HST motor (FIG. 4).

Therefore, the rotation control of the chopping and conveying hydrostatic continuously variable transmission 21 is performed when the vehicle speed is lower than a predetermined traveling speed, and the speed of the reaping device 4 is changed in synchronization with the traveling speed as a low speed mode. When the speed is higher than the traveling speed, the controller 60 is configured to output a control so as to shift the speed of the reaping device 4 in synchronization with the traveling speed as a high speed mode.
When controlling the rotation of the cutting device 4 in accordance with the vehicle speed, if the same control output is made from low speed to high speed, the control accuracy varies due to the characteristics of the load and the hydraulic mechanism, and hunting and follow-up delay (according to changes in the vehicle speed) There is a concern that the follow-up of the rotational change of the reaping device 4 is delayed).
In the present application, the traveling speed is detected by the vehicle speed sensor 61. When the vehicle speed is lower than the predetermined traveling speed, the reaping device 4 is shifted in synchronization with the traveling speed as the low speed mode. When the vehicle speed is higher than the predetermined traveling speed, the high speed mode is selected. The controller 60 outputs the control to the hydrostatic continuously variable transmission 21 for cutting and conveying so that the cutting device 4 shifts in synchronization with the traveling speed. A stable rotation is output to the device 4 to improve the reliability of the cutting operation. In addition, at high speed, the followability is improved to stabilize the cutting operation.

That is, as shown in FIG. 2, the speed of the reaping device 4 is changed in synchronization with the increase / decrease of the traveling speed. The output for increasing / decreasing the output rotation of the device 21 is executed in the low speed mode during the low speed running based on the predetermined running speed, and is executed in the high speed mode during the high speed running.
Note that the number of rotations of the reaping device 4 is determined by the opening of the reaping HST motor 52 of the reaping and conveying hydrostatic continuously variable transmission 21, so that the reaping is performed at the same vehicle speed in both the low speed mode and the high speed mode. The opening of the HST motor 52 is the same. Therefore, FIG. 10 shows from the rotation stop of the reaping device 4 to the normal rotation, until the cutting HST motor stop position (opening is zero) during deceleration control. The output time is shown.
62 is a rotation sensor of the reaping device 4 (FIG. 5).

The control output from the controller 60 to the hydrostatic continuously variable transmission 21 for cutting and conveying is an intermittent output in the low-speed mode, and the output is shortened and the output time is shortened.
Therefore, delicate rotation control can be performed and operability can be improved.

FIG. 6 shows the acceleration output state in the low speed mode, and FIG. 7 shows the deceleration output state in the low speed mode.
Further, the control output to the hydrostatic continuously variable transmission 21 for harvesting and conveying by the controller 60 is an intermittent output even in the high-speed mode, but is configured to output a long output cycle and a long output time.
Therefore, the followability of the rotation of the reaping device 4 with respect to the change in the traveling speed can be improved, and the reaping work can be performed at a high speed, and the working efficiency can be improved.
FIG. 8 shows the acceleration output state in the high speed mode, and FIG. 9 shows the deceleration output state in the high speed mode.
When the controller 60 determines that the vehicle speed has changed from the low-speed mode to the high-speed mode range or the traveling speed at which the output mode is switched from the high-speed mode to the low-speed mode range, the output mode is set based on the change in the vehicle speed within a predetermined time. Automatically select and control.

That is, the vehicle speed changes from the low speed mode to the high speed mode, or from the high speed mode to the low speed mode near the predetermined speed, and the vehicle speed is set to the low speed mode corresponding to the change in the vehicle speed. When the vehicle is switched from the high speed mode to the high speed mode, since the vehicle speed changes, the high speed mode is selected and controlled.
On the contrary, when switching from the high speed mode to the low speed mode, the vehicle speed changes by deceleration, so the low speed mode is selected and controlled.
Therefore, the lack of hunting and followability when the output mode is switched is prevented.
When a deceleration output is made to the hydrostatic continuously variable transmission 21 for harvesting and conveying, the rotational position of the output shaft of the electric motor that moves the trunnion shaft of the HST motor 52 for harvesting of the hydrostatic continuously variable transmission 21 for harvesting and conveying is determined. As the detected motor position sensor 63 approaches the set stop position, the output time of the intermittent output is reduced.
Therefore, in the low-speed mode, even if it is in a range where the mowing device 4 may be stopped by the load of the mowing device 4, an unexpected stop of the mowing device 4 can be avoided, and the stability and reliability of the mowing operation can be improved. Improve.
When the speed increasing output is performed to the harvesting and conveying hydrostatic continuously variable transmission 21, the output is stopped for a certain time after the output, and then output again.

If acceleration output is performed continuously, the rotation may not follow the control and may overshoot (excessive rotation). However, in this application, by providing an output signal transmission stop time after output, The controller 60 determines the follow-up state of rotation with respect to the operation of the hydraulic motor of the conveying hydrostatic continuously variable transmission 21 to prevent hunting and overshoot (excessive rotation).
When the deceleration output and the acceleration output are alternately operated within a predetermined time alternately a predetermined number of times or more, the controller 60 until the deceleration output and the acceleration output are finished so that the deceleration output / acceleration output is halved. Adjust the output time.
Thereby, it is possible to detect hunting and suppress overshoot.
When the deceleration output and the speed increase output are repeatedly operated alternately over a predetermined number of times within a predetermined time, until the deceleration output and the speed increase output are finished in order to reduce the subsequent deceleration / speed increase output every predetermined time. Adjust the output time.
Therefore, the hunting operation is suppressed.

In addition, when the deceleration output and the acceleration output are alternately output more than a predetermined number of times within a certain time, the controller 60 may stop the deceleration / acceleration output for a certain time.
Wait for the detection value of the sensor to stabilize, start output again, and prevent hunting.
The motor position sensor 63 indicates the motor position value indicating the rotational position of the output shaft of the electric motor that moves the trunnion shaft of the cutting HST motor 52 during traveling and during deceleration output. When it is detected that the position has been reached, the deceleration output is stopped.
When the vehicle is decelerated at a slow speed that is an acceleration side position less than a predetermined position from the predetermined stop position, if the deceleration output is further performed, the rotation of the reaping device 4 stops, so the deceleration output is stopped and the reaping is performed. The rotation stop of the device 4 is avoided, and a slow cutting operation is made possible.
That is, in a general HST mechanism, it is common sense that the operation stop is set further on the deceleration side than the actual hydraulic output stop position. However, in the control of the hydrostatic continuously variable transmission 21 for cutting and conveying, When reaching the acceleration side position less than the predetermined stop position from the predetermined stop position, the deceleration output is stopped.

At the start of traveling from the airframe stop state, when the rotational speed of the reaping device 4 reaches a predetermined value or more when the vehicle speed is less than a predetermined value, the rotational position of the output shaft of the electric motor that moves the trunnion shaft of the reaping HST motor 52 at this time Even if the motor position value is stored and the subsequent deceleration output is performed, the motor position is controlled so that the motor position is not decelerated and output below the stored motor position value.
The rotation stop of the cutting device 4 due to the deceleration output is avoided.
A main transmission lever position detection sensor 65 for detecting the operation position of the main transmission lever 13 is provided (FIG. 5), and the hydraulic pump of the hydrostatic continuously variable transmission 12 for traveling based on the detection value of the main transmission lever position detection sensor 65 is provided. It is configured to operate at an opening of 14 to set the traveling speed of the aircraft.
The opening of the hydraulic pump 14 is configured to be set based on the detection information of the operation position of the main transmission lever 13 and the position information before operation of the main transmission lever 13 before operation.
Therefore, since the opening of the hydraulic pump 14 can be set by information calculated from the pre-operation position information of the main transmission lever 13 and the operation position detection information of the main transmission lever 13 before operation, the operator can make a sudden main transmission. The acceleration / deceleration of the vehicle speed when the lever 13 is operated can be reduced (or increased), and a sudden change in the vehicle speed can be avoided.

That is, if the hydraulic pump 14 is simply opened and closed so that the traveling speed according to the operation position of the main transmission lever 13 is reached, the vehicle speed may change suddenly. Is opened and closed by information calculated from the pre-operation position information and the detection information of the operation position of the main transmission lever 13, so that the degree of acceleration until reaching the traveling speed according to the operation position of the main transmission lever 13 is calculated in advance. Therefore, the ride comfort is improved, and the durability of the hydrostatic continuously variable transmission 12 for traveling is improved.
The controller 60 performs a moving average process on the detection value of the main shift lever position detection sensor 65, selects a solenoid (not shown) for energizing the valve of the hydrostatic continuously variable transmission 12 for traveling, and moves and averages the energized current. The setting is applied based on the processing.
A work presence / absence sensor 68 for detecting whether or not the reaping device 4 is in operation is provided (FIG. 5), and when the reaping device 4 is not in operation, it is used for traveling with respect to the operating position of the main transmission lever 13 as compared to during operation. The response of changing the opening of the hydraulic pump 14 of the hydrostatic continuously variable transmission 12 is delayed.
Therefore, it is possible to give a change to the response of the shifting operation during the road running and the cutting operation, and it is possible to perform a shifting operation rich in mobility during the cutting operation in the field while enabling smooth shifting in the road driving. Become.

The work presence / absence detection sensor 68 is configured to detect whether the reaping device 4 is not working or is working by a reaping / threshing clutch sensor 69 that turns on / off transmission to the reaping device 4 and the threshing device 2. The moving average processing time of the controller 60 based on the detection value of the shift lever position detection sensor 65 is longer (slower) during non-work than during work.
The combine is configured to be capable of mounting a working mechanism (not shown) such as a knotter / cutter, and provided with presence / absence sensing means 71 for detecting whether or not the working mechanism is mounted (FIG. 5). The maximum value of the working rotation speed of each part is configured to be switched.
For example, when a knotter is installed, there is a risk that the weight will increase and binding errors may occur during high-speed work, but when the knotter is installed, the vehicle speed is automatically suppressed, so the vehicle speed according to the work implement is easy. And prevent clogging and breakage caused by accidentally exceeding the allowable range of the work implement.
The control unit 6 is provided with a parking brake pedal 72. When the parking brake pedal 72 is depressed, the traveling hydrostatic continuously variable transmission 12 is set to the neutral position (neutral position for forward and backward travel). The control unit 6 is provided with a separate pedal 73, which outputs to an actuator (not shown) for increasing and decelerating the hydrostatic continuously variable transmission 12 for traveling by means of not only the parking brake pedal 72 but also the pedal 73. The hydrostatic continuously variable transmission 12 is set to the neutral position.

Then, the neutrality of the traveling hydrostatic continuously variable transmission 12 is held by the brake pedal 73, and the main transmission lever 13 is returned to the neutral position or until the main transmission lever 13 is operated again. The neutral of the hydrostatic continuously variable transmission 12 for traveling by the pedal 73 is maintained.
Therefore, when the main transmission lever 13 is decelerated and the main transmission lever 13 is decelerated and the stepping pedal 73 is stepped on, the airframe always stops, and in this state, until the cutting and conveying hydrostatic continuously variable transmission 21 is driven, It can be scraped and is safe and easy to operate.
Reference numeral 74 denotes an HST position sensor.
The traveling hydrostatic continuously variable transmission 12 is configured such that load control is performed to keep the engine rotation constant.

When the load of the threshing device 2 rises and the engine speed decreases, the vehicle speed is slowed down by the hydrostatic continuously variable transmission 12 for traveling to reduce the amount of cereals supplied to the threshing device 2 and reduce the load. Reduce and maintain constant engine rotation (FIG. 14).
In this case, when there is a turning operation for turning the airframe during load control, the fuel injection amount is increased so that the engine speed does not decrease due to the traveling load during turning, and the speed before the turning operation is maintained. (FIG. 15).
Therefore, turning can be performed smoothly.
That is, during turning, an output value corresponding to the operation position of the main transmission lever 13 is output to the traveling hydrostatic continuously variable transmission device 12 to maintain the state immediately before the turning operation. When the sensor 75 is turned on, the control of the load control is released, and the vehicle speed is reduced in order to keep the engine rotation constant.
Therefore, the start of load control after turning can be performed accurately, and the operation of the threshing apparatus 2 can be stabilized.
Reference numeral 76 denotes a power steering position sensor.

(Operation of Example)
When the machine is run, the reaping device 4 harvests and transports the grain culm in the field, the cereals conveyed by the reaping device 4 are taken over by the synchro front supply transport device 11, and the synchro front supply transport device 11 The cocoon is delivered to the cereal supply / conveyance device 10, and the cereal supply / conveyance device 10 conveys the cereal at a constant speed and supplies it to the threshing chamber of the threshing device 2 for threshing.
When the traveling device 3 tilts the main transmission lever 13 by the traveling hydrostatic continuously variable transmission 12, the traveling hydrostatic continuously variable transmission 12 transmits the constant rotation of the engine 22 steplessly and transmits it. The traveling speed can be changed, and the rotation transmitted to the reaping device 4 and the front supply / conveying device 11 for synchronization is also shifted in synchronization with the traveling speed of the traveling device 3 by the hydrostatic continuously variable transmission 21 for reaping and conveying. Therefore, the cutting device 4 is transmitted with the optimum work rotation speed according to the traveling speed.
That is, when the main transmission lever 13 is tilted, a constant rotation of the engine 22 is steplessly shifted by the traveling hydrostatic continuously variable transmission 12 and transmitted to the traveling device 3, and is synchronized with the traveling speed of the traveling device 3. Thus, the rotation transmitted to the reaping device 4 and the synchro front supply / conveyance device 11 is also shifted by the reaping and conveying hydrostatic continuously variable transmission 21.

Therefore, the rotation control of the cutting and conveying hydrostatic continuously variable transmission 21 is performed when the vehicle speed is lower than the predetermined traveling speed, the reaping device 4 is shifted in synchronization with the traveling speed as a low speed mode, and the vehicle speed is set to the predetermined traveling speed. At higher speeds, the controller 60 is configured to perform control output so that the reaping device 4 shifts in synchronization with the running speed as a high speed mode, so that the control accuracy varies depending on the characteristics of the load and the hydraulic mechanism. However, at low speed, the hydrostatic continuously variable transmission 21 for cutting and conveying outputs a stable rotation to the cutting device 4 to improve the certainty of the cutting work, and at high speed to improve the followability and stabilize the cutting work.
The control output to the hydrostatic continuously variable transmission 21 for cutting and conveying by the controller 60 is an intermittent output in the low speed mode, and is configured to output with a short output period and a short output time, so that delicate rotation Control can be performed and operability can be improved.

The control output to the hydrostatic continuously variable transmission 21 for cutting and conveying by the controller 60 is an intermittent output even in the high speed mode, but is configured to output a long output period and a long output time. The followability of the rotation of the reaping device 4 with respect to the change in the traveling speed can be improved, and the reaping operation by high-speed traveling can be performed, so that the work efficiency can be improved.
When the controller 60 determines that the vehicle speed is a traveling speed at which the output mode is switched from the low speed mode to the high speed mode or a traveling speed at which the output mode is switched from the high speed mode to the low speed mode, the controller 60 is based on a change in the vehicle speed within a predetermined time. Therefore, even if the vehicle speed changes from the low speed mode to the high speed mode or from the high speed mode to the low speed mode, the low speed mode and the high speed are controlled. Since the mode is selected according to the mode of change of the vehicle speed at that time, an optimal control mode can be selected.

For example, when the vehicle speed is switched from the low speed mode to the high speed mode, the vehicle speed changes at an increased speed. Therefore, the high speed mode is selected and controlled.
On the contrary, when switching from the high speed mode to the low speed mode, the vehicle speed changes by deceleration, so the low speed mode is selected and controlled.
Therefore, the lack of hunting and followability when the output mode is switched is prevented.
When a deceleration output is made to the hydrostatic continuously variable transmission 21 for harvesting and conveying, the rotational position of the output shaft of the electric motor that moves the trunnion shaft of the HST motor 52 for harvesting of the hydrostatic continuously variable transmission 21 for harvesting and conveying is determined. Motor position sensor to detect Since the output time of the intermittent output decreases as the motor position sensor 63 approaches the set stop position, the mowing device 4 may be stopped by the load of the mowing device 4 in the low speed mode. Even within the range, it is possible to avoid inadvertent stopping of the mowing device 4 and to improve the stability and reliability of the mowing work.

When the speed increasing output is performed to the harvesting and conveying hydrostatic continuously variable transmission 21, the output is paused for a certain time after the output, and then is output again. However, in this application, by providing an output signal transmission stop time after the output, the hydraulic motor of the hydrostatic continuously variable transmission 21 for cutting and conveying is provided in the present application. The controller 60 determines the follow-up state of the rotation with respect to the operation to prevent hunting and overshoot (excessive rotation).
When the deceleration output and the acceleration output are alternately output repeatedly over a predetermined number of times within a predetermined time, the controller 60 adjusts the output time so that the deceleration / acceleration output is halved. Suppress the shoot.
When the deceleration output and acceleration output are repeatedly output alternately over a predetermined number of times within a certain time, the output time is adjusted so that the subsequent deceleration / acceleration output is reduced every certain time, thus suppressing the hunting operation. .

Further, if the controller 60 is configured to repeatedly output the deceleration / acceleration output a predetermined number of times alternately within a predetermined time, the detection value of the sensor and the like can be stabilized if the deceleration / acceleration output is stopped for a predetermined time. After waiting for this, output is started again to prevent hunting.
The motor position sensor 63 indicates the motor position value of the rotational position of the output shaft of the electric motor that moves the trunnion shaft of the cutting HST motor 52 of the cutting and conveying hydrostatic continuously variable transmission 21 during traveling and deceleration output. When it is detected that the acceleration side position less than the predetermined stop position has been reached, the deceleration output is stopped. Further, when the deceleration output is performed, the rotation of the reaping device 4 is stopped, but the deceleration output is stopped, the rotation of the reaping device 4 can be prevented from being stopped, and a very low speed reaping operation can be performed.

At the start of traveling from the state where the machine body is stopped, when the rotational speed of the reaping device 4 reaches a predetermined value or more when the vehicle speed is less than the predetermined value, the reaping HST motor of the transpiration conveying hydrostatic continuously variable transmission 21 at this traveling speed Since the motor position value of the output position of the output shaft of the electric motor that moves the 52 trunnion shafts is stored and the motor position is controlled so that the motor position is not decelerated below the stored motor position value even if subsequent deceleration output is performed. The rotation stop of the cutting device 4 due to the output is avoided.
Thus, the traveling hydrostatic continuously variable transmission 12 for shifting the traveling speed of the traveling device 3 increases / decreases in accordance with the tilting operation amount of the main transmission lever 13, but further, the traveling hydrostatic continuously variable transmission for traveling. The motor swash plate 17 of the hydraulic motor 16 of the apparatus 12 is also configured to be able to switch the inclination angle in two steps (the configuration of the switching operation means is arbitrary), and is configured to be able to switch between normal traveling and high speed traveling. The cutting operation (standard operation and overturning operation) is performed at the traveling speed (standard side), and the traveling time is shortened by traveling at the high traveling speed (high speed side).

Therefore, in the present application, a dedicated hydropneumatic continuously variable transmission 21 for cutting and conveying is provided separately from the hydrostatic continuously variable transmission 12 for traveling, and the hydrostatic continuously variable transmission 12 for traveling is provided. And the hydrostatic continuously variable transmission 21 for harvesting and conveying are configured so that the rotation transmitted to the harvesting device 4 and the front-side feeding and conveying device 11 for synchronization is synchronized with the traveling speed of the traveling device 3. A specific action of the reaping device 4 by the hydrostatic continuously variable transmission 21 for reaping and conveying will be described in detail below.
The travel speed of the travel device 3 is changed by operating the main shift lever 13, and the standard work line A for increasing the transmission rotation at a predetermined rate relative to the travel speed of FIG. Then, the lowering work line B, which is accelerated at a higher rate than that of the standard work line A, is selectively employed to drive the reaping device 4 and the synchro front supply / conveyance device 11.

Since the transmission rotation to the reaping device 4 and the synchro front supply / conveyance device 11 is shifted by the reaping and conveying hydrostatic continuously variable transmission 21, the gear is normally synchronized with the traveling speed, but under predetermined conditions. Since the reaping device 4 and / or the synchro front supply / conveyance device 11 can be driven by the reaping and feeding hydrostatic continuously variable transmission 21 alone, the working mode can be expanded and the versatility can be improved.
In other words, since the cutting and transporting hydrostatic continuously variable transmission 21 can drive the cutting and transporting device 4 and the synchro front supply and transport device 11 at a sufficient number of revolutions even during a predetermined traveling speed from the state where the body is stopped. The reaping device 4 and the threshing device 2 can be driven stably immediately after the start of traveling, and the reaping operation and the threshing operation can be performed stably and reliably.
Further, when the rotation of the traveling hydrostatic continuously variable transmission 12 from the traveling hydrostatic continuously variable transmission 12 to the traveling device 3 is stopped, the synchro front supply / conveyor 11 is driven by the cutting and conveying hydrostatic continuously variable transmission 21 alone. Since the front supply / conveyor device 11 for synchro can be driven in the traveling stop state, the supply operation for supplying hand-cut cereals to the front supply / conveyor device 11 for synchros and the cereal supply / conveyor device 10 can be facilitated and harvested In addition, the workability and operability of the threshing operation can be improved.

Thus, the rotation of the engine 22 is transmitted to the intermediate pulley 28, and the intermediate pulley 28 transmits the rotation to the intermediate transmission shaft 31 of the case via the intermediate shaft 29 and the intermediate gear 30. And the cereal supply / conveyance intermediate output shaft 41 and the hydrostatic continuously variable transmission 21 for harvesting / conveying.
The rotation transmitted to the threshing transmission bevel gear 32 is transmitted to the barrel 34 and driven.
The rotation of the intermediate transmission shaft 31 is transmitted to the grain supply / intermediate output shaft 41, and the rotation of the grain supply / transport intermediate output shaft 41 is input from the terminal side of the grain supply / transport apparatus 10, 10 is driven.
Accordingly, the cereal supply / conveyance intermediate output shaft 41 generates a constant rotation from the engine 22 regardless of the hydrostatic continuously variable transmission 12 for traveling and the hydrostatic continuously variable transmission 21 for harvesting and conveying. It is transmitted to the koji supply / conveyance device 10, and the cereal supply / conveyance device 10 and the handling cylinder 34 always rotate in the same relationship.

On the lower side of the grain supply / conveyance intermediate output shaft 41, there is provided the harvesting HST input shaft 37 of the hydrostatic continuously variable transmission 21 for harvesting and conveying, whose rotation is transmitted by the intermediate gear 36 for harvesting. The rotation of the transfer intermediate output shaft 41 is input to the pump of the chopping transfer hydrostatic continuously variable transmission 21 and the rotation shifted from the motor of the chopping transfer hydrostatic continuously variable transmission 21 is the cutting HST output shaft 38. The reaping HST output shaft 38 drives and rotates the reaping device 4 and the synchro front supply / conveyance device 11 by the reaping intermediate output shaft 39 and the transport synchro output shaft 40.
Each of the above-described embodiments is illustrated or described individually or mixedly for easy understanding, and these embodiments including a block diagram and the like can be variously combined with each other.

  DESCRIPTION OF SYMBOLS 1 ... Airframe frame, 2 ... Threshing device, 3 ... Traveling device, 4 ... Mowing device, 5 ... Glen tank, 10 ... Grain supply / conveyance device, 11 ... Front supply conveyance device for synchro, 12 ... Hydrostatic pressure for traveling Continuously variable transmission, 13 ... main transmission lever, 14 ... hydraulic pump, 15 ... pump swash plate, 16 ... hydraulic motor, 17 ... motor swash plate, 18 ... mission case, 21 ... hydrostatic continuously variable transmission for cutting and conveying Equipment: 22 ... Engine, 26 ... Input pulley, 27 ... Mission case, 28 ... Intermediate pulley, 29 ... Intermediate shaft, 30 ... Intermediate gear, 31 ... Intermediate transmission shaft, 32 ... Throwing transmission bevel gear, 33 ... Threshing transmission shaft , 34 ... Handling cylinder, 35 ... Processing cylinder, 36 ... Intermediate gear for cutting, 37 ... Cutting HST input shaft, 38 ... Cutting HST output shaft, 39 ... Intermediate output shaft for cutting, 40 ... Output shaft for conveying synchronization, 41 ... Grain supply / intermediate delivery Shaft, 42 ... Kara, 43 ... Drive gear, 44 ... Cutting threshing clutch, 45 ... Cutting intermediate output pulley, 46 ... Cutting intermediate input pulley, 47 ... Belt, 50 ... Gear case, 52 ... HST motor for cutting, 60 ... Controller, DESCRIPTION OF SYMBOLS 61 ... Vehicle speed sensor, 63 ... Motor position sensor, 65 ... Main shift lever position detection sensor, 68 ... Work presence / absence detection sensor, 69 ... Cutting / threshing clutch sensor, 71 ... Presence / absence detection means, 72 ... Parking brake pedal, 73 ... Scratching Pedal, 75 ... cereal sensor.

Claims (6)

A reaping device (4) is provided in front of the traveling device (3) capable of continuously changing the traveling speed by the hydrostatic continuously variable transmission (12) for traveling, and a threshing device (3) is disposed above the traveling device (3). 2), and the reaping device (4) is driven by a hydrostatic continuously variable transmission (21) for cutting and conveying in synchronism with the traveling speed of the traveling device (3). The continuously variable transmission (21) is configured to be rotationally controlled by a controller (60) that outputs a control to an electric motor that rotates the trunnion shaft of the HST motor for cutting of the hydrostatic continuously variable transmission (21) for cutting and conveying. The controller (60) executes a low-speed mode in which the vehicle speed is lower than the predetermined travel speed, and executes a low-speed mode in which the vehicle motor is intermittently output to the electric motor at a predetermined output cycle and output time. Is configured to execute a high-speed mode in which output is intermittently performed with an output cycle and output time longer than that of the low-speed mode, and when the deceleration output is performed to the hydrostatic continuously variable transmission (21) for cutting and conveying, the electric motor The motor position sensor (63) for detecting the rotation position of the output shaft of the controller is configured to reduce the output time of the intermittent output as it approaches the preset stop position, and the controller (60) for the hydraulic transfer for cutting and conveying During the deceleration output to the variable continuously variable transmission (21), the motor position sensor (63) sets the motor position value of the rotational position of the output shaft of the electric motor to a speed increasing side position that is less than a predetermined value from a predetermined stop position. When it is detected that the deceleration output has been reached, the deceleration output is stopped. When the vehicle starts running from the state where the vehicle is stopped, the rotational speed of the reaping device (4) is less than a predetermined value when the vehicle speed is less than a predetermined value. Upon reaching the above, combined stored motor position value at this time, even if the subsequent deceleration output, which is configured not to decelerate the output of the motor position below the storage motor position value of the. In Claim 1, the control output to the hydrostatic continuously variable transmission (21) for harvesting and conveying by the controller (60) is controlled by automatically selecting an output mode based on a change in vehicle speed within a predetermined time. If it is determined that the vehicle speed has changed from the speed in the range corresponding to the low speed mode to the speed in the range corresponding to the high speed mode, the high speed mode is selected, and conversely, the vehicle speed is determined from the speed in the range corresponding to the high speed mode. A combine that is configured to select and control the low-speed mode when the speed is switched to a range corresponding to the low-speed mode .   In Claim 1, when performing the speed-up output to the said hydrostatic continuously variable transmission (21) for chopping conveyance, it was set as the structure which pauses an output for a fixed time after an output, and outputs again after that. Combine.   2. The configuration according to claim 1, wherein when the deceleration output and the acceleration output of the controller (60) are alternately output a predetermined number of times alternately within a predetermined time, the output time is adjusted so that the deceleration and the acceleration output are each halved. Combine that is characterized by that.   In Claim 1, when the deceleration output and the acceleration output from the controller (60) are repeatedly output alternately over a predetermined number of times within a predetermined time, the subsequent deceleration or acceleration output is made smaller every predetermined time. A combine that is characterized by adjusting the output time.   2. The deceleration output or acceleration output from the controller (60) is stopped for a certain time when the deceleration output and acceleration output from the controller (60) are alternately output more than a predetermined number of times within a certain time. Combine that is characterized by its composition

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