JPH0454763Y2 - - Google Patents

Description

[Detailed explanation of the idea] [Industrial application field] The present invention relates to a harvester having a threshing device.

[Conventional technology]

The harvesting machine feeds the grain culms harvested in the reaping section to the threshing device using the conveying device, and the harvested grain culms are threshed by the handling cylinder in the threshing device, and are sorted by the swinging sorting device. The fine grains are taken out. The oscillating sorting device consists of a oscillating sorting board, a chaff sheave, a stroke rack, etc., and grains that have been sorted by specific gravity on the oscillating sorting board are further sorted by passing through the gaps between the fins of the chaff sheave.

Recently, the inclination angle (fin angle) of the fins of the chaff sheave has been configured to be changeable, and the fin angle, that is, the gap between the fins, has been changed so that the flow rate is within a certain range in accordance with the grain flow rate. A threshing device with improved sorting accuracy has been developed.

In addition, in the case where processing cylinders are arranged side by side, the quality of the threshing device is determined by the amount of the second reduced material returned to the processing cylinders. For this reason, in the case of a threshing device in which processing cylinders are arranged side by side, it is desirable to change the fin angle according to the amount of secondary reduction material.

On the other hand, in a harvester, the amount of grain harvested is approximately proportional to the traveling speed of the machine. For this reason, when automatically adjusting the Finn angle so that the amount of secondary reduction product is within a predetermined range, the amount of secondary reduction product also changes as the traveling speed changes, and the Finn angle is also changed and adjusted. Since the range of the amount of secondary reduction product to be controlled remains constant even if the amount changes, automatic adjustment of the Finn angle becomes impossible. Especially when running at a very low speed, the grain flow rate will be low and the Finn angle will be in a high sorting accuracy state and will be automatically adjusted to increase the amount of secondary reduction product, but if the grain flow rate is very low. Because of the small amount, the amount of the second reduction product did not increase, and the amount of the second reduction product was repeatedly reduced, and there was a risk that the grains would be husked or crushed during the reduction.

〔the purpose〕

The present invention was developed in view of the above circumstances, and its purpose is to provide a harvesting machine that enables sorting in accordance with the running speed of the machine and prevents grain loss and damage. It is in.

〔composition〕

The present invention is designed to automatically adjust the fin angle of the chaff sheave in the threshing device to achieve a set threshing throughput, and the set threshing throughput is changed in accordance with the traveling speed of the machine. It is something.

〔Example〕

The present invention will be described below based on drawings showing embodiments thereof.

FIG. 1 is an external perspective view of a harvester according to the present invention. In the figure, 3 is a threshing device mounted on the upper part of the machine body above the traveling crawler 1, and the reaping section K is located at the front part of the machine body and is composed of a dividing rod 4, a cutting blade 2, a pulling device 7, etc. The grain culms harvested by the threshing device 3 are sent to the threshing device 3 via upper and lower conveying devices (not shown), where they are threshed, and the threshed grains are sent to the paddy tank 5.

In the figure, 9 is an operation column installed in front of the driver's seat 8, and 10 is a vertical conveyance device, the end of which faces the starting end of the feed chain 12 of the grain culm transfer device 11. A grain culm sensor 6 is provided nearby to detect the feeding of grain culm to the threshing device. Note that the grain culm sensor 6 is not limited to this position, but may be placed on the side of the starting end of the grain culm transfer device 11, or within the conveyance path of the vertical conveyance device 10, etc., or in a harvester equipped with an automatic handling depth adjustment device. In the machine,
It may also be configured to be used in common with a sensor provided for culm length detection. The grain culm transfer device 11 is composed of a feed chain 12 and a ram 13, and is provided along the handling opening of the threshing device 3.

FIG. 2 is a partially cutaway vertical sectional view of the threshing device 3. The threshing device 3 has a handling barrel 17 having a large number of handling teeth 16, 16... mounted on a shaft in a handling chamber 15 formed in the upper part of the machine casing 14, and a handling opening parallel to the axial direction of the handling barrel 17. At the same time, a receiving net 18 is stretched in the lower part of the handling chamber 15, and furthermore, a swinging sorting device 1 is installed in the lower part of the handling chamber 15, which is substantially parallel to the axial length direction of the handling cylinder 17.
9. Furthermore, a processing chamber 50 for reprocessing the second reduction product is provided at the upper right side of the handling barrel 17 (near the center of the machine), and inside this processing chamber 50, the handling barrel extends in the axial direction. A processing cylinder 51 having a large number of handling teeth 52, 52, .

The swinging sorting device 19 includes a swinging sorting board 20 extending in an inclined manner, a chaff sheave 21 of a variable angle type (to be described later) provided at the lower rear of the swinging sorting board 20, and a straw connected to the rear of the chaff sheave 21. It is composed of a rack 22 and the like, and is configured to swing in the axial direction of the handling cylinder 17 by swing arms 23 and 24 that swing in conjunction with a drive source.

Further, below the swinging sorting device 19, there is a first grain board 2.
5 and the first grain outlet (first mouth) 27 consisting of the first screw 26, and the second grain outlet (second mouth) consisting of the second flow grain plate 28 and the second screw 29.
30 is formed.

The grains that have fallen into the first grain take-out section 27 are fed from the first screw 26 to the paddy tank 5, and the grains that have fallen into the second grain take-out section 30 are sent from the second screw 29 to the second throat tube by the blower 47. 48 and is blown up into the roof plate of the threshing device 3 and dropped onto the processing cylinder 51 from a processing cylinder cover 53 protruding above the processing chamber 50 for re-sorting. The second screw 29 is provided with a second rotation sensor 69 that detects the number of revolutions of the screw 29, and the processing cylinder cover 53 is provided with a second rotation sensor 69 that detects the amount of reduced material returned to the processing cylinder. 60 are provided.

A grain sheave 32 is provided below the chaff sheave 21 in the air passage 31.
A winnowing device 33 is provided on the wind raising side. Then, the airflow from this Karasaki device 33
After being swept away by the dust collector, the dust is discharged from the machine through an air passage 31 through a dust exhaust port (third port) 36 at the rear of the machine.

A dust suction/exhaust device 37 using an axial fan is provided at the rear and upper part of the stroke rack 22;
An upper suction cover 38 is placed above the dust suction/exhaust device 37.
In addition, a lower suction cover 39 is provided below, and the suction port 40 of the dust suction/exhaust device 37 is connected to the air path 31.
The air outlet 41 is opened to the side, and the air outlet 41 is connected to the dust outlet 3.
It opens towards 6.

Above the upper suction cover 38, a fourth gutter 43 is provided which extends diagonally upward from both ends to form a fourth gutter 44, which collects the prickly grains taken out from the culm after threshing, that is, from the waste straw. The stroke rack 22 is configured to be returned upward.

FIG. 3 is a side sectional view of the vicinity of the fin angle changing operation lever shown together with a part of the chaff sheave. The chaff sheave 21 is located between the left and right frame members (not shown) extending in the longitudinal direction of the aircraft among the rectangular frame members.
A large number of fins 21b extending in the left-right direction of the fuselage body are arranged in parallel in the front-rear direction, and each upper part is pivotally supported on a frame member. The lower part of each fin 21b is pivotally supported by one adjusting rod 21c extending in the front-rear direction, and the middle of the rotation shaft 21d is fixed to the front part of the adjusting rod 21c. The rotation shaft 21d is pivotally supported at a position above the adjustment link 21c, and the front end of the tension spring 21e is locked to the upper part of the rotation shaft 21d. Tension spring 21
The other end of e is locked in place within the threshing chamber. A push-pull wire 21f is attached to the lower end of the rotation shaft 21d.
One end of the push-pull wire 21f is locked, and the other end of the push-pull wire 21f is attached to a rotating piece 72 attached to the base end of an operating lever 71 provided on the front side of the threshing device 3 on the side of the driver's seat 8. It is pivotally supported.

Therefore, by pulling the push-pull wire 21f, the lower part of the rotation rod 21d is rotated rearward, and the adjustment rod 21c is moved rearward, and the fin 21b is erected and the fin angle (between the fin 21b and the adjustment rod 21c
The angle formed between the fins 21b and 21b becomes larger, and the gap between the fins 21b becomes larger. On the other hand, push-pull wire 2
When 1f is pressed, the lower part of the rotation rod 21d is rotated forward, the adjustment rod 21c is moved forward, the fins 21b are tilted, the fin angle r becomes small, and the gap between the fins 21b becomes small.

The operating lever 71 is provided on the front right side of the threshing device 3, and can be operated by a worker seated in the driver's seat 8. An operation panel 70 is attached to the side of the operation lever 71 on the front side of the threshing device 3, and a frame 77 that is U-shaped in plan view and whose front part is open is attached to the rear surface of the operation panel 70. An operating lever 71 is pivotally supported on the side surface of the frame 77. The front part of the operating lever 71 passes through an elongated hole formed in the operating panel 70 and protrudes forward, and the lower part of a rectangular rotating piece 72 is fixed to the base end of the operating lever 71. One end of the push-pull wire 21f is locked.

The front part of the frame 77 has a rotating shaft 75 in the vertical direction.
is mounted on a shaft, and a spiral feeding member 76 is fixed to the rotating shaft 75 at both ends and at an appropriate portion in the middle. Further, a lower end portion of the rotating shaft 75 projects downward from the frame 77, and this projecting portion is inserted into the gear box 74. This gear box 74 is attached to a motor 73 with its output shaft at the front, and the driving force of the motor 73 is transmitted to a rotating shaft 75 by a worm gear to rotate a feeding member 76. The aforementioned operating lever 71 is pressed toward the rotating shaft 75 by an appropriate method (not shown), and is adapted to be engaged between the spirals of the feed member 76.

Therefore, when the motor 73 is driven and the feeding member 76 rotates, the operating lever 71 is sent into the spiral of the feeding member 76 and moves in the vertical direction. It is also possible to remove the lock and operate it manually. When the operating lever 71 is rotated manually or by reverse rotation (or forward rotation) of the motor 73 in the direction shown by the solid line (or broken line) in FIG. 3, the push-pull wire 2
If 1f is pulled (or pressed), the fins 21b stand up (or tilt), and the gap between the fins becomes larger (or smaller). A lever position detection sensor 78 using a potentiometer is provided at the base end pivot portion of the operating lever 71, and detects a voltage corresponding to the rotational position of the operating lever 71, and thus a voltage corresponding to the fin angle. It is output from the sensor 78.

FIG. 4 is a circuit diagram of the control system of the proposed machine. In the figure, 80 is a control device using a microcomputer, including a CPU 81, RAM 82, and ROM 8.
3, an input interface 84 and an output interface 85.

Input port in input interface 34
At a ₀ , the output of a vehicle speed sensor 58 using a potentiometer that is installed at the base end of the vehicle speed lever for changing the speed of the aircraft and outputs a potential according to the amount of rotation is sent to the A/D converter 59. The vehicle speed is digitally converted and inputted, and based on the output of the A/D converter 59, the vehicle speed is identified into three levels: high speed, medium speed, and low speed.

Input port in input interface 84
The detection signal of the second sensor 60 is converted into a digital signal by the A/D converter 61 and input to _a1 . Input port a ₂ has the aforementioned chaf sheave 2.
The output of a lever position detection sensor 78, which is provided at the base end of the first fin angle changing operation lever 71 and uses a potentiometer, is converted into a digital signal by an A/D converter 62 and input.

A threshing switch ₆₃ that is turned on when the threshing clutch is in the engaged state is connected to the input port a3, and when the threshing switch 63 is turned on, the input port _a3 becomes high level.

A reaping switch ₆₄ that is turned on when the reaping clutch is in the engaged state is connected to the input port a4, and when the reaping switch 64 is turned on, the input port _a4 becomes high level.

An automatic switch ₆₅ that is turned on when the fin angle of the chaff sheave should be automatically adjusted is connected to the input port a5, and when the automatic switch 65 is turned on, the input port _a5 becomes high level.

A grain changeover switch ₆₆ is connected to the input port _a6 , which is operated to switch depending on whether the grain to be threshed is rice or wheat. The switch 66 is turned on to set the level.

A wet/dry changeover switch ₆₇ is connected to the input port _a7 , which is operated depending on whether the grain to be threshed is dry or wet. Switch 6 to set it to high level
7 is turned on.

The grain culm sensor 6 that detects the conveyance of grain culm to the above-mentioned threshing device is connected to the input port _a8 , and when the sensor 6 detects the conveyance of the grain culm, the input port
a ₈ becomes high level.

The output of the switch circuit 68 is given to the input port _a9 , and the switch circuit 68 is turned on and off by the output of the second rotation sensor 69, and the second rotation sensor 69 detects the low rotation of the second screw 29. When the output of the sensor 69 becomes high level upon detection of , the switch circuit 68 is turned on and the input port _a9 becomes high level. Further, the output of the switch circuit 68 is given to a light emitting diode LED 99 whose one end is grounded to the body.

A switch circuit 86 is connected to the output port _b1 of the output interface 85, and when the switch circuit 86 is turned on, the light emitting diode 91 lights up. The output port _b1 outputs a high level signal when the control device 80 is not operating normally, and the light emitting diode 91 is lit by the high level signal.

A switch circuit 87 is connected to the output port _b2 , and when the switch circuit 87 is turned on, the light emitting diode 92 lights up. The output port _b2 outputs a high level signal when each sensor or switch is not operating normally, and the light emitting diode 92 is lit by the high level signal.

A switch circuit 88 is connected to the output port _b3 , and when the switch circuit 88 is turned on, the automatic lamp 93 is turned on. The output port _b3 outputs a high level signal when the automatic switch 65 for automatically adjusting the fin angle of the chaff sheave 21 is turned on, and the automatic lamp 93 is turned on by the high level signal.

A switch circuit 89 is connected to the output port _b4 , and when the switch circuit 89 is turned on, the excitation coil 94c of the electromagnetic relay 94 is excited. This electromagnetic relay 94 has an interlocking normally open contact 94a and a normally closed contact 94b, and the normally open contact 94a connects the power supply line and one end of the motor 73 for driving the operation lever 71 ( The normally closed contact 94 is interposed between the
b is interposed between the same terminal of the motor 73 and body ground. The output port _b4 outputs a high level signal when tilting the fin 21b of the chaff sheave 21 (when reducing the fin angle).

A switch circuit 90 is connected to the output port _b5 , and when the switch circuit 90 is turned on, the excitation coil 95c of the electromagnetic relay 95 is excited. This electromagnetic relay 95 has an interlocking normally open contact 95a and a normally closed contact 95b, and the normally open contact 95a connects the power supply line with the other end of the motor 73 (the terminal that becomes high voltage when the motor 73 rotates forward). It is interposed between
Further, the normally closed contact 94b is interposed between the same terminal of the motor 73 and the body ground. Applicable output port
_b5 outputs a high level signal when raising the fin 21b of the chaff sheave 21 (when increasing the fin angle).

Therefore, when the output port b ₄ becomes a high level, the excitation coil 94c of the electromagnetic relay 94 is excited, its normally open contact 94a is closed, and the motor 73 rotates in reverse, and when the output port b ₅ becomes a high level, the excitation coil 94c of the electromagnetic relay 94 is excited. The excitation coil 95c is excited and its normally open contact 95
a is closed and the motor 73 is driven to rotate in the normal direction.

A switch circuit 96 is connected to the output port _b6 , and when the switch circuit 96 is turned on, an alarm buzzer 97 and a light emitting diode 98 light up. As described later, the output port _b6 outputs a high level signal when the amount of the second reduction product does not fall within a predetermined range even if the fin angle of the chaf sheave 21 reaches the upper or lower limit of the control range in automatic adjustment. do.

The operation of the harvester having such a configuration will be explained.
When manually adjusting the fin angle, turn off the automatic switch 65, operate the operating lever 71 to disengage from the feed member 76, and rotate the lever 71 to release the push-pull wire 21f. When pulled or pressed, the fins 21b stand up or tilt, and the fin angle increases or decreases.

When the machine is run in this state to perform harvesting and threshing operations, the grain culms cut by the reaping section K are fed to the grain culm transfer device 11 of the threshing device 3.
The grain culm inherited by the grain culm transfer device 11 is inserted with its tip side into the handling chamber 15 through the handling port of the threshing device 3, and is then transferred to the handling tooth 16 of the handling barrel 17 which is being driven to rotate.
16..., and the threshed grains and other grated materials pass through the receiving net 18 and fall onto the swinging sorting device 19, and are subjected to specific gravity sorting by the swinging of the device 19. The first grains, such as fine grains, which have passed through the gaps between the fins 21b, 21b... of the chaff sieve 21 fall into the first grain take-out section 27, and the second reduced products and third grains are raised in the tumbler device 33. The grains are blown onto the straw rack 22 by the wind, hit the prevention cloth 42, fall onto the straw rack 22, are loosened by the swinging action of the straw rack 22, and are re-sorted. The second reduced products, such as grains with branches and stalks, fall into the second grain removal section 30, are blown up from the second screw 29 into the second thrower cylinder 48 by the blower 47, and are re-sorted in the processing cylinder 51. For relatively large pieces of straw, etc., use the Karawaki device 33.
The dust is transferred to the rear with the interference of the prevention sheet 42 by the wind blown from the air, and is discharged from the dust outlet 36 to the outside of the machine, while relatively lightweight debris is sucked through the suction port 40 of the dust suction/discharge device 37. , is discharged outside the machine from the exhaust port 41.

Next, automatic adjustment of the fin angle in the chaff sheave 21 will be explained based on the flowcharts of FIGS. 5 to 8. First, when the key switch is turned on, the alarm counter BZ indicating that the buzzer 97 has sounded, the cutting flag K indicating that the cutting operation is in progress, and the cutting start flag D indicating that it is time to start cutting are all reset (=0). Furthermore, each condition is set in accordance with the grain to be threshed.

FIG. 6 is a flowchart of condition setting control. In the condition setting control, first, it is determined based on the state of the grain changeover switch 66 whether the grain to be threshed is rice or wheat. In the case of rice in which the grain changeover switch 66 is turned off, the value α for the rice is set as the upper limit α of the appropriate range of the amount of secondary reduction product, and the value β for the rice is set as the lower limit β. do. Furthermore, the value L for rice is set as the upper limit value (maximum value) L of the control range when automatically adjusting the angle of the fins 21b in the chaff sheave 21.

Next, it is determined whether the rice to be threshed is dry wood or wet wood depending on the state of the dry/wet selector switch 67.
When the moisture-drying switch 67 is turned on, the wet material value Ss for rice is set as the lower limit value (minimum value) S of the control range when automatically adjusting the angle of the fin 21b, and the wet-drying switch 67 When dry wood is turned off, set the dry wood value Sik for rice.

Furthermore, the set value of the fin angle M that is set at the start of automatic adjustment is changed according to the vehicle speed detected by the vehicle speed sensor 58. That is, when the vehicle speed is high, the set value M of the fin angle is set to the value Mik for rice, when the vehicle speed is intermediate, Mih, and when the vehicle speed is low, Mit is set.

On the other hand, in the case of wheat where the grain changeover switch 66 is turned off, the same conditions are set, and the value αm for wheat is set as the upper limit α of the appropriate range of the amount of secondary reduction products, and the value βm for wheat is set as the lower limit β. In addition, the value Lm for barley is set as the upper limit L of the control range of the Finn angle during automatic adjustment.

Next, the lower limit value S of the control range of the Finn angle during automatic adjustment is set depending on whether the wheat to be threshed is dry wood or wet wood. That is, in the case of dry wood with the wet/dry selector switch 67 turned off, the value Smk of the dry wood in wheat is used as the lower limit S, and in the case of wet wood with the wet/dry selector switch 67 turned on, the value Sms of the wet wood in wheat is used as the lower limit value S. Set each.

Furthermore, the set value of the fin angle M set at the start of automatic adjustment is changed in accordance with the set vehicle speed. That is, in the case of high speed, the value Mit of the low speed state in the case of rice mentioned above is set, in the case of intermediate speed, the value Mmh of wheat is set, and in the case of low speed, the low speed value Mmt of wheat is set. do.

In this way, each setting value differs depending on rice and wheat, and dry wood and wet wood, and the upper and lower limit setting values αi, βi of the appropriate range of the amount of secondary reduction substances for rice, and the setting values αm, βi for wheat, The relationship between βm is αi<αm,
βi<βm.

This is because culm breakage occurs more easily in the case of wheat than in the case of rice, so it is necessary to increase the amount of the second reducer by setting the lower limit higher than in the case of rice, within the appropriate range of the amount of the second reducer. By setting in this way, the amount of reduced material to the chaff sieve 21 is increased, and the contamination of the culm pieces with the first material is reduced, thereby improving the sorting accuracy.

In addition, the upper and lower limit set values of the control range of the Finn angle during automatic adjustment are different for rice and wheat, and the lower limit set values are also different for rice, wheat, and their dry and wet conditions. , upper limit setting value is Li>Lm, lower limit setting value is Sis>Sik>
Sms > Smk. This is because the chaff sieve of rice has poor leakage compared to wheat, and wet wood has worse leakage than dry wood, so if the fin angle becomes small, there is a risk of dust accumulating on the chaff sieve and causing clogging. Therefore, the control range of Huynh's angle for rice is generally larger than that for wheat, and the control range for wet wood is larger than that for dry wood.

Furthermore, the setting value of the Huynh angle at the beginning of cutting is different for rice and wheat.
In addition, this setting value differs depending on the vehicle speed, and the value for rice and high speed is larger than the value for wheat and low speed, respectively, so that Mik>Mih
＞Mit＞Mmh＞Mmt. This is because in the case of wheat, there are many culm breaks, etc., so it is necessary to increase the amount of the secondary reduction substance, and in the case of rice, the leakage is poor, so the setting limit at the start of automatic adjustment in the case of rice is It is necessary to make the horns larger than for wheat to improve leakage by reducing sorting accuracy, and when the vehicle speed is high, the grain flow rate increases and the amount of secondary reduction material also increases. On the other hand, at low speeds, the grain flow rate decreases and the amount of secondary reduction material decreases, so the fin angle set at the start of automatic adjustment at high speeds is set larger than that at low speeds, and This is because it is necessary to reduce the sorting accuracy so that the amount of materials does not become too large.

After setting such conditions, the control device 80 determines whether or not the reaping work has started using the mowing start flag D, and the mowing start flag D is reset (D=
0), it is assumed that the reaping work has not yet started, and the memorized value P of the fin angle is stored as the fin setting angle M at the time of starting mowing.

In such a state, when the automatic switch 65 is turned on to automatically adjust the fin angle, and the threshing switch 63 is turned on with the threshing clutch in the engaged state to drive the threshing device 3, the control device 80 first adjusts the fin angle. The motor 73 is continuously driven in normal rotation so that the lower limit value S is reached, and the fin angle is determined from the detection result p of the lever position detection sensor 78, and when the lower limit value S is reached, the drive of the motor 73 is stopped.

When the machine is run in this state and reaping work and threshing work are started, the harvested grain culm is conveyed to the threshing device 3, the grain culm sensor 6 is turned on, the automatic lamp 93 is turned on, and the automatic Notify that adjustments can be made. Then, when the reaping switch 64 with the reaping clutch in the engaged state is on, and the reaping flag K is in the reset state (K
= 0), the sorting is performed in the high precision sorting state S with the smallest Finn angle during the predetermined time _T1 ,
Wait for the predetermined time T ₁ to elapse, and then calculate the Finn angle,
The motor 73 is continuously driven in the reverse direction to achieve the set angle M at the start of mowing described above. Then, the drive of the motor 73, which detects that the fin angle has reached the set angle M based on the detection value p of the lever position detection sensor 78, is stopped, and the reaping flag K indicating that reaping work has started is set (K =1).

This is because when the threshing operation starts, the amount of threshing is not constant, so the amount of the second reduced material is unstable, and the detection result of the second sensor 60 is also extremely unstable. Automatically adjusting _the fin angle based on
The fin angle is sorted in the lowest state S of the control range in automatic adjustment, that is, the state with the highest sorting accuracy, and the fin angle is immediately set to the set angle M after a predetermined time T ₁ in which the threshing amount is stabilized, After achieving such a state, the fin angle is controlled centering on the state of this fin angle M by intermittently driving the fin 21b in accordance with the amount of the second reduction substance based on the detection result of the second sensor 60. I have to.

On the other hand, in a non-working state where either the automatic switch 65 or the threshing switch 63 is off or in a state where the fin angle is manually adjusted, the automatic lamp 93 is turned off, and in a working state where both switches 65 and 63 are on, the grain culm sensor 6 If the grain culm is not detected, the automatic lamp 93 is blinked, and the motor 73 is continuously driven to set the fin angle to the lower limit value S in the automatic adjustment, and the fin 21b is kept in a high sorting accuracy state where it is most tilted. The grain culm is in a state where it can be transported.

Next, control of the Finn angle based on the amount of the second reduced product detected by the second sensor 60 will be explained based on the flowchart of FIG.

First, the control device 80 determines whether the traveling speed of the aircraft detected by the vehicle speed sensor 58 is higher than a predetermined value.
Check whether the speed is below a predetermined value. In the case of high speed, the upper limit value α and lower limit value β of the appropriate range of the amount of secondary reduction product determined according to the type of grain as described above are increased by predetermined amounts Δα and Δβ, respectively. α + Δα, β + Δβ, and when the speed is low, the upper limit value α and lower limit value β of the amount of secondary reduction product, which are also determined according to the type of grain, are decreased by the predetermined amount Δα, Δβ. Change settings to α-Δα and β-Δβ, respectively.

In such a state, check the alarm counter BZ to see if the buzzer 97 has already sounded, and if the alarm counter BZ is in the reset state (BZ=0) and the buzzer 97 has not sounded yet,
The fin angle p corresponding to the lever position detected by the lever position detection sensor 78 is read as the stored value P. When the amount of the second reduced material detected by the second sensor 60 exceeds the upper limit α (or below the lower limit β) for proper sorting by the chaff sieve 21, the fin angle is within the control range during automatic adjustment. Upper limit L
It is determined from the detection value p of the lever position detection sensor 78 whether or not the value is greater than or equal to the lower limit value S (or less than the lower limit value S), and if it is not the upper limit value L (or the lower limit value S),
The motor 73 is rotated in reverse (or forward) for a short predetermined period of time to increase (or decrease) the fin angle by a predetermined amount Δp, thereby increasing (or decreasing) the gap between the fins 21b.
As a result, the amount of grains etc. passing through the gap is increased (or decreased), and the amount of grains to the second take-out section 30 is decreased (or increased). When such control is performed, the mowing start flag D is set (D=1),
The alarm counter BZ is set to a reset state (BZ=0). If the amount of secondary reduction product does not fall within the predetermined range (α to β) even with the change Δp in the fin angle due to the short-time drive of the motor 73, the motor 73 is operated again.
3 is driven for a short time, the fin angle is changed by Δp again, and the motor 73 is driven intermittently until the amount of the second reduced product falls within a predetermined range.

In this case, the appropriate range of the amount of the second reduction product (α to β)
is set according to the traveling speed of the aircraft,
In the case of high speed, the upper limit value and lower limit value are set large, and in the case of low speed, the upper limit value and lower limit value are set small. This is because the traveling speed of the machine and the grain flow rate are approximately proportional; at high speeds, the amount of secondary reductant increases, and conversely, at low speeds, the amount of secondary reductants decreases. The dead zone (appropriate range) of the automatic adjustment of the fin angle is set so that the amount of secondary reduction material increases overall, and conversely decreases at low speeds, so that control corresponding to the grain flow rate can be performed. It is.

By driving the motor 73 for a predetermined time, the Finn angle changes by Δp, and if the amount of secondary reduction product is within a predetermined range, the motor 73 is not driven and the Finn angle is not changed, but the lever position detection sensor 78 detects The value p is the Finn angle (P+Δp or P−) expected from the motor drive despite the drive of the motor 73.
Δp), or if the fin angle is changing even though it has not been changed, it is assumed that the operating lever 71 has been manually operated and the fin angle has been changed. Manual holding control is performed to give priority to adjustment of the fin angle by operation. This manual holding control prohibits automatic adjustment and maintains the state of the manually operated fin angle, and after a predetermined time has elapsed, the fin angle is within the range of automatic adjustment (S ~
Restart automatic adjustment as L).

On the other hand, if the amount of the second reduced product is not within the appropriate range (α to β) and the amount of the second reduced product does not fall within the appropriate range (α to β) even by intermittent driving of the motor 73 by automatic adjustment, the motor 73 is intermittently driven until the fin angle reaches the upper limit value L (or lower limit value S) of the control range. When the fin angle reaches the lowest (or highest) state during automatic adjustment where the fin angle exceeds the upper limit value L (or the lower limit value S or less) of the control range, the alarm counter BZ sets the upper limit (or lower limit) of the fin angle. The duration of the state is measured, and the count is incremented by 1 at regular intervals. The chaff sieve 21 performs sorting in such a state, but the amount of the second reduced product does not fall within the appropriate range within the predetermined time until the count content of the alarm counter BZ reaches _T2 , and the upper limit (or lower limit) of the Finn angle ) If the condition continues for this predetermined period of time, the buzzer 97 will sound and the light emitting diode 98 will be lit.

This is because if the amount of the second reduction product is not within the appropriate range, the fin angle of the chaff sheave 21 is used as the upper or lower limit of the control range in automatic adjustment to select the amount of the second reduction product to be within the appropriate range. If the amount of the second reduced material does not fall within the appropriate range even after continuing for a predetermined period of time, it is an abnormal condition such as clogging in the chaff sheave, and automatic adjustment of the fin angle within the predetermined range in the chaff sheave 21 does not allow the amount of the second reduced material to fall within the appropriate range. is not within the appropriate range, the buzzer 97 sounds and the light emitting diode 98 lights up.
This system is designed to notify the driver that an abnormality has occurred.

During such work, the second grain removal section 30
If the number 2 rotation sensor 69 detects that the amount of the number 2 objects falling on the shaft has increased, the number 2 screw 29 has become overloaded, and its rotation speed has fallen below a predetermined value, the fin of the chaf sheave 21 Prohibits automatic adjustment of the fins, turns off the automatic lamp 93, and continuously reverses the motor 73 so that the fin angle reaches the upper limit L of the control range in automatic adjustment, increasing the amount of grain passing between the fins 21b. First grain removal section 27
By increasing the amount of grains that fall into the second grain removal section 30, the amount of second grains that fall into the second grain removal section 30 is reduced.
In this case, the fin angle p at the time when the No. 2 screw 29 becomes overloaded is stored as a memory value P, and when the overload is eliminated, the fin angle is immediately set to the value p to restore the state. to automatically adjust the fin angle.

At the end of one cycle of reaping work, there is no transported grain culm and the grain culm sensor 6 is turned off, but at the end of such reaping work, the amount of threshed grains is not constant, just like at the start of work, and the second return Since the quantity of goods is also unstable,
If the fin angle is controlled based on the amount of the second reduction product, the sorting accuracy will be significantly degraded, so automatic adjustment based on the amount of the second reduction product is prohibited, the automatic lamp 93 is set to a blinking state, and the grain culm sensor 6 is turned off. The fin angle p is stored as a memory value P, and the motor 73 is continuously driven so that the fin angle of the chaff sheave 21 reaches the lower limit value S of the automatic adjustment control range after a predetermined time _T3 , so that the fin is most tilted. In other words, the selection is performed in the most accurate state. At this time, the reaping flag K is set to a reset state (K=0). After finishing one stroke of reaping work, turning to the next step and starting reaping work again, the grain culm is detected by the sensor 6, and during the predetermined time _T1 when the grain flow rate is low, the chaff sheave 21
Grain sorting can be carried out in a high sorting accuracy state where the fin angle has reached the lower limit value S. However, after a predetermined time T ₁ has elapsed, the fin angle is set to the memorized value at the end of reaping, and in that state, the second Automatic adjustment of the Finn angle based on the amount of reductant is resumed.

Therefore, even at the beginning of cutting in one stroke,
Initially, sorting is performed in a high sorting accuracy state, and after a predetermined period of time, the fin angle is continuously driven so that it becomes the final fin angle when automatically adjusting the fin angle in the previous process, and the fin angle is automatically adjusted in this state. will be resumed.

On the other hand, automatic fin angle adjustment will be explained when the harvester having such a configuration performs manual threshing work without reaping.

Automatic switch 65 to automatically adjust the fin angle
When the threshing clutch is engaged and the threshing switch 63 is turned on, the fin angle of the chaff sheave 21 becomes smaller, resulting in the highest sorting accuracy, as in the above-mentioned harvesting operation. When the grain culm to be threshed is inserted into the handling chamber 15 in this state, the grain culm sensor 6 is turned on. In this case, since it is manual threshing, the reaping clutch is in the disengaged state and the reaping switch 64 is in the off state, so the fin angle is immediately automatically adjusted without setting the fin angle to the standard state M. Therefore, the automatic adjustment is started at a fin angle state with high selection accuracy, and the automatic adjustment is performed centering around this fin angle state. The subsequent automatic adjustment is similar to the automatic adjustment during the harvesting operation described above, and the fins 21b are intermittently driven so that the amount of the second reduction product becomes a predetermined value.

In the above-described embodiment, the Finn angle was automatically adjusted based on the second reduction amount, but instead of this, it is automatically adjusted based on the first flow rate, the third flow rate, the grain culm supply amount, etc. It may also be a configuration.

〔effect〕

According to the present invention, the threshing processing amount set in the automatic adjustment of the fin angle is changed according to the running speed of the machine, and at high speeds, there is a risk that the second grain will be unnecessarily mixed into the first grain removal section. In addition, at low speeds, all threshed grains are reprocessed as secondary reduction products, thereby preventing the occurrence of crushed grains, etc.
This has excellent effects such as making it possible to sort according to the traveling speed of the aircraft.

[Brief explanation of the drawing]

The drawings show an embodiment of the present invention.
The figure is an external perspective view of the proposed machine, Figure 2 is a vertical sectional view of the threshing device, Figure 3 is a side view of the main parts of the chaff sheave and the vicinity of the operating lever, Figure 4 is an electronic circuit diagram of the main parts of the proposed machine, 5 to 7 are flowcharts for explaining the operation. 3... Threshing device, 6... Grain culm sensor, 11...
Grain culm transfer device, 17... handling cylinder, 21... chaff sieve, 21b... fin, 27... first grain removal section, 29... second screw, 30... second grain removal section, 50... ...Processing chamber, 51...Processing cylinder,
58...Vehicle speed sensor, 60...Second sensor, 63
... Threshing switch, 64 ... Reaping switch, 65
...Automatic switch, 66...Grain changeover switch,
67...Dry/wet selector switch, 69...Second rotation sensor, 71...Operation lever, 73...Motor, 76
...Feeding member, 78...Lever position detection sensor, 8
0...Control device, 97...Buzzer.

Claims (1)

[Scope of utility model registration request] A means for changing the fin angle of a chaff sheave in a threshing device, a means for detecting the amount of threshing processed, a means for automatically adjusting the fin angle so as to achieve a set amount of threshing based on the detection result, and a means for adjusting the running speed of the machine body. A harvester comprising: a detection means; and a means for changing the threshing processing amount set in the automatic adjustment in accordance with the detection result of the traveling speed.