JP2022055396A - Combine harvester - Google Patents

Abstract

To provide a combine harvester that can suppress an area in which a continuously variable transmission occupies a space of the periphery of an engine while retaining high work efficiency.SOLUTION: When a travel speed (V) of a travel device is a low speed equal to or less than a first set speed (V1), a rotational speed output from an engine is transmitted to the travel device and a reaping device via a continuously variable transmission for increasing/decreasing a rotational speed, and a transmission for increasing/decreasing a rotational speed output from the continuously variable transmission. When the travel speed (V) of the travel device is a higher speed than the first set speed (V1), a rotational speed output from the engine is transmitted to the travel device via the continuously variable transmission and the transmission, and is transmitted to the reaping device via a belt (62) wound around a first pulley supported by an input shaft of the continuously variable transmission and a second pulley supported by a rotational shaft connected to an output shaft of the transmission via a clutch (54).SELECTED DRAWING: Figure 6

Description

The present invention relates to a combine equipped with a continuously variable transmission that accelerates / decelerates the traveling speed of a traveling device and the driving speed of a cutting device.

In the conventional combine, when the traveling speed of the traveling device is low, the cutting device is driven at a constant driving speed, and when the traveling speed of the traveling device is high, the driving speed of the cutting device is made to follow the traveling speed of the traveling device. Techniques for improving sex are known. (See Patent Document 1)

Japanese Unexamined Patent Publication No. 2000-203468

However, in the technique of Patent Document 1, the maximum output required for the continuously variable transmission becomes large, and it is necessary to mount a large continuously variable transmission, and the continuously variable transmission excessively occupies the space around the engine. I was afraid.

Therefore, a main object of the present invention is to provide a combine capable of suppressing an area occupied by a continuously variable transmission in a space around an engine while maintaining high work efficiency.

The present invention that solves the above problems is as follows.
That is, according to the first aspect of the present invention, the traveling device (2) is provided on the lower side of the machine frame (1) on which the engine is mounted, and the cutting device (3) is provided on the front side of the machine frame (1). In a combine equipped with a threshing device (4) behind the device (3),
When the traveling speed (V) of the traveling device (2) is a low speed equal to or lower than the first set speed (V1), the rotation speed output from the engine is a stepless transmission that accelerates or decelerates the rotation speed. It is transmitted to the traveling device (2) and the cutting device (3) via the (27) and the transmission (28) that accelerates / decelerates the rotation speed output from the stepless speed changer (27). When the traveling speed (V) of (2) is higher than the first set speed (V1), the rotation speed output from the engine is the stepless transmission (27) and the transmission (28). The first pulley (60) transmitted to the traveling device (2) and supported by the input shaft (31) of the stepless transmission (27), and the output shaft (35) of the transmission (28). And a belt (62) wound around a second pulley (61) supported by a rotating shaft (55) connected via a clutch (54), and is transmitted to the cutting device (3). It is a combine characterized by the fact that.

According to the second aspect of the present invention, when the traveling speed (V) of the traveling device (2) is low, the clutch (54) is connected to the tension arm provided behind the belt (62). When the tension of the belt (62) is relaxed by retracting (63) from the belt (62) and the traveling speed (V) of the traveling device (2) is high, the clutch (54) is connected. The combine according to claim 1, wherein the tension arm (63) is released and the tension arm (63) is advanced toward the belt (62), and the tension of the belt (62) is tensioned.

According to the third aspect of the present invention, when the traveling speed (V) of the traveling device (2) is high, the traveling speed (V) of the traveling device (2) is higher than the first set speed (V1). The combine according to claim 2, wherein when the speed is higher than the second set speed (V2), which is also low, the clutch (54) is disengaged and the tension of the belt (62) is maintained. be.

The invention according to claim 4 is the combine according to claim 3, wherein the first set speed (V1) and the second set speed (V2) can be set according to the seed pair of the grain culm to be planted in the field. Is.

The invention according to claim 5 is that when the traveling speed (V) of the traveling device (2) is high and the cutting device (3) has a grain clutch to be transported to the threshing device (4). The combine according to any one of claims 2 to 4, wherein the clutch (54) is disengaged and the tension of the belt (62) is maintained.

The invention according to claim 6 is the combine according to any one of claims 1 to 5, wherein the clutch (54) is a one-way clutch.

According to the invention according to claim 1, when the traveling speed (V) of the traveling device (2) is a low speed equal to or lower than the first set speed (V1), the rotation speed output from the engine is the rotation speed. It is transmitted to the traveling device (2) and the cutting device (3) via the stepless speed change device (27) that accelerates and decelerates and the transmission (28) that accelerates and decelerates the rotation speed output from the stepless speed change device (27). When the traveling speed (V) of the traveling device (2) is higher than the first set speed (V1), the rotation speed output from the engine is the stepless transmission (27) and the transmission (28). The first pulley (60) transmitted to the traveling device (2) and supported by the input shaft (31) of the stepless transmission (27), and the output shaft (35) of the transmission (28). It is configured to be transmitted to the cutting device (3) via a belt (62) wound around a second pulley (61) supported by a rotating shaft (55) connected via a clutch (54). Therefore, the maximum output required for the stepless speed changer (27) can be reduced and replaced with a small stepless speed changer (27), which is occupied by the stepless speed changer (27) and the transmission (28). It is possible to suppress the space around the engine. Further, when the traveling speed (V) of the traveling device (2) is low, the driving speed of the harvesting device (3) is made to follow the traveling speed (V) of the traveling device (2) to efficiently produce the grain culm. It can be cut and harvested.

According to the invention of claim 2, in addition to the effect of the invention of claim 1, when the traveling speed (V) of the traveling device (2) is low, the clutch (54) is engaged. When the tension arm (63) provided behind the belt (62) is retracted from the belt (62) to relax the tension of the belt (62) and the traveling speed (V) of the traveling device (2) is high. The clutch (54) is disengaged, the tension arm (63) is advanced toward the belt (62), and the tension of the belt (62) is tensioned. ) Can be easily formed to switch the configuration to be transmitted to.

According to the invention of claim 3, in addition to the effect of the invention of claim 2, when the traveling speed (V) of the traveling device (2) is high, the traveling speed (V) of the traveling device (2) is high. ) Is slower than the first set speed (V1) and higher than the second set speed (V2), the clutch (54) is disengaged and the tension of the belt (62) is maintained. Therefore, it is possible to prevent the states of the clutch (54) and the belt (62) from being frequently changed and improve the durability of the clutch (54) and the belt (62).

According to the invention of claim 4, in addition to the effect of the invention of claim 3, the first set speed (V1) and the second set speed (V2) are set to the seed pair of the culm planted in the field. Since it can be set accordingly, it is possible to adjust the switching of the transmission method of the cutting device (3) according to the type of grain culm to be planted in the field.

According to the invention of claim 5, in addition to the effect of the invention of any one of claims 2 to 4, when the traveling speed (V) of the traveling device (2) is high, the cutting device is used. If there is a grain to be transported to the threshing device (4) in (3), the clutch (54) is disconnected and the tension of the tension of the belt (62) is maintained, so that the cutting device (3) is maintained. ) To the threshing device (4) can be quickly threshed.

According to the invention of claim 6, in addition to the effect of the invention of any one of claims 1 to 5, the clutch (54) is a one-way clutch, so that the configuration of the clutch (54) can be simplified. Can be formed. Further, since the rotation speed of the engine transmitted to the rotation shaft (55) via the belt (62) is not transmitted to the output shaft (35), malfunction can be prevented.

It is a front view of a combine. It is a plan view of a combine. It is a left side view of the combine. It is explanatory drawing of the drive mechanism of a reaping device. It is a connection diagram of a controller. This is the first driving method of the reaping device. This is the second driving method of the reaping device.

As shown in FIGS. 1 to 3, the combine is provided with a traveling device 2 consisting of a pair of left and right crawlers traveling on the soil surface under the machine frame 1, and harvests grain culms in the field on the front side of the machine frame 1. A reaping device 3 is provided. Further, a threshing device 4 for threshing and sorting the grain culms harvested by the reaping device 3 is provided on the rear left side of the reaping device 3, and a control unit 5 on which the operator is boarded is provided on the rear right side of the reaping device 3. Has been done.

An engine room 6 for mounting an engine is provided on the lower side of the control unit 5, and a grain tank 7 for storing grains that have been threshed and sorted by the threshing device 4 is provided on the rear side of the control unit 5. , The grains stored in the Glen tank 7 are discharged to the outside by a discharge auger (not shown) connected to the Glen tank 7.

A front panel 10 is provided in front of the cockpit of the cockpit 5, and a side panel 11 is provided on the left side of the cockpit.

On the left side of the front panel 10, a touch panel type monitor that displays the traveling speed V and the like of the traveling device 2 and inputs the set speeds V1 and V2 of the traveling device 2 and the set torques T1 and T2 of the threshing device 4 to be described later. 21 is provided, and an operation lever 22 for operating the turning of the traveling device 2 and the raising and lowering of the cutting device 3 is provided on the right side.

A main shift lever 25 for operating a continuously variable transmission 27 that accelerates / decelerates the rotation speed and switches the rotation direction output from the engine is provided on the front portion of the side panel 11, and is provided on the rear side of the main shift lever 25. Is provided with an auxiliary shift lever 26 that operates a transmission 28 that accelerates / decelerates the rotational speed output from the continuously variable transmission 27. Further, the operating angle of the main shifting lever 25 is measured by an angle sensor 25A such as a potentiometer attached to the lower part of the main shifting lever 25, and the operating angle gutter of the auxiliary shifting lever 26 is located at the lower part of the auxiliary shifting lever 26. It is measured by an angle sensor 26A such as a mounted potentiometer. A limit sensor can be used instead of the angle sensors 25A and 26A.

When the main shift lever 25 is in the neutral position, the rotation speed output from the continuously variable transmission 27 becomes zero. When the main shift lever 25 is tilted forward from the neutral posture, the rotation direction output from the continuously variable transmission 27 becomes the same positive rotation as the rotation direction transmitted from the engine, and when the tilt angle of the front tilt posture becomes large. The rotation speed output from the continuously variable transmission 27 becomes faster, and the rotation speed output from the continuously variable transmission 27 becomes slower when the inclination angle of the front tilting posture becomes smaller. When the main shift lever 25 is tilted backward from the neutral posture, the rotation direction output from the continuously variable transmission 27 is the reverse rotation to the rotation direction transmitted from the engine, and the tilt angle of the rear tilt posture. When the value becomes large, the rotation speed output from the continuously variable transmission 27 becomes high, and when the inclination angle of the rear tilting posture becomes small, the rotation speed output from the continuously variable transmission 27 becomes slow.

When the auxiliary speed change lever 26 is tilted to a low speed position, the rotation speed transmitted from the continuously variable transmission device 27 is decelerated by the transmission 28 and transmitted to the traveling device 2 and the cutting device 3 to be tilted to the medium speed position. In that case, the rotational speed transmitted from the continuously variable transmission 27 is not accelerated or decelerated but is transmitted to the traveling device 2 and the cutting device 3, and when tilted to a high speed position, it is transmitted from the continuously variable transmission 27. The rotation speed is increased and transmitted to the traveling device 2 and the cutting device 3.

As shown in FIG. 4, the rotational speed output from the engine is transmitted to the input shaft 31 of the continuously variable transmission 27 via the pulley 30. The rotation speed transmitted to the input shaft 31 is output to the output shaft 32 after being accelerated or decelerated in the continuously variable transmission 27.

The rotation speed output to the output shaft 32 is transmitted to the gear 34 via the fixed gear 33 of the output shaft 32. The gear 34 is rotatably fixed to the output shaft 35. The rotation speed transmitted to the gear 34 is transmitted to the counter shaft 37 via the gear 36.

The rotation speed transmitted to the counter shaft 37 is transmitted to the gear 41 via the gear 40. The rotational speed transmitted to the gear 41 is transmitted to the output shaft 43 via the gear 42. The rotation speed transmitted to the output shaft 43 is transmitted to the traveling device 2 to drive the traveling device 2.

The rotation speed transmitted to the counter shaft 37 is interlocked with the gear 52 via the gear 50 or the gear 51 fixed to the counter shaft 37, and the rotation speed transmitted to the gear 52 is via a key (not shown). It is transmitted to the output shaft 35.

The gear 52 is formed by arranging gears having different pitch diameters. In the present embodiment, the gear 52 includes a gear 52A that engages with the gear 50 and a gear 52B that has a larger pitch diameter than the gear 52A that engages with the gear 51. Further, the gear 52 moves in the left-right direction on the output shaft 35 via the shifter 53 operated by the auxiliary shift lever 26. As a result, the length of the transmission 28 in the left-right direction can be suppressed, and the transmission device including the continuously variable transmission 27 and the transmission 28 can be miniaturized.

The rotation speed transmitted to the output shaft 35 is transmitted to the rotation shaft 55 via the clutch 54. The rotation speed transmitted to the rotating shaft 55 is transmitted to the cutting device 3 via a pulley 56 fixed to the rotating shaft 55 and a belt (not shown) to drive the cutting device 3. Thereby, the rotation speed transmitted to the output shaft 35 can be transmitted to the rotation shaft 55 with a simple structure, or the transmission can be cut off. As the clutch 54, a one-way clutch is used in which the rotational speed transmitted to the output shaft 35 can be transmitted to the rotary shaft 55, but the rotational speed transmitted to the rotary shaft 55 cannot be transmitted to the output shaft 35. It is preferable to do.

A pulley (“first pulley” in claim) 60 is provided on the left side of the pulley 30, and a pulley (“second pulley” in claim) 61 is provided on the right side of the pulley 56 on the rotating shaft 55. There is. A belt 62 is wound around the pulley 60 and the pulley 61, and a tension arm 63 for tensioning and relaxing the tension of the belt 62 is provided behind the belt 62. In this embodiment, the diameters of the pulley 60 and the pulley 61 are formed to be the same, but the speed increase ratio of the pulley 60 and the pulley 61 is the maximum speed increase ratio of the transmission device including the continuously variable transmission and the transmission. It is preferable to generate so as to be larger than.

When the traveling speed V of the traveling device 2 is set to a set speed (“first set speed” in the claim) V1 or less, or when the load of the grain removal device 4 is set to a low load of T1 or less. The tension arm 63 retracts from the belt 62, the tension of the belt 62 is relaxed, and the rotational speed output from the engine is transmitted to the cutting device 3 via the continuously variable transmission 27 and the transmission 28. Further, in this case, the clutch 54 is connected, and the rotation speed of the output shaft 35 is transmitted to the rotation shaft 55 via the clutch 54. As a result, the cutting device 3 can be driven in synchronization with the traveling device 2. It is possible to efficiently cut and harvest the grain culms planted in the field.

On the other hand, in the case of a high speed exceeding the set speed V1 in which the traveling speed V of the traveling device 2 is set, or in the case of a low load of the set torque T1 or less in which the load of the grain removal device 4 is set, the tension arm 63 is a belt 62. The tension of the belt 62 is tense as it moves forward toward, and the rotational speed output from the engine is cut through the pulley 60, the belt 62, and the pulley 61 without going through the continuously variable transmission 27 and the transmission 28. It is transmitted to the device 3. In this case, the clutch 54 is disconnected. As a result, the maximum output required for the continuously variable transmission 27 can be reduced and replaced with the small-capacity continuously variable transmission 27, and the transmission device including the continuously variable transmission 27 and the transmission 28 can be miniaturized. be able to.

<Controller connection diagram>
As shown in FIG. 5, the combine controller 15 is formed of a processing unit 16 including a CPU and the like, and a storage unit 17 including a ROM, RAM, a hard disk drive, a flash memory, and the like.

The processing unit 16 connects or disconnects the clutch 54 and the tension arm 63 as compared with the set speed V1 in which the traveling speed V of the traveling device 2 is set and the set torque T1 in which the load of the threshing device 4 is set. To move forward or backward with respect to the belt 62.

The storage unit 17 has a set speed V1 input via a monitor 20 provided on the front panel 10, a set speed V2 slower than the set speed V1 (“second set speed” in the claim), and a set torque. T1 and a set torque T2 smaller than the set torque T1 are stored.

On the input side of the controller 15, a speed sensor 2A for measuring the traveling speed V of the traveling device 2, a grain sensor 3A for measuring the presence or absence of a harvested grain in the cutting device 3, and a load of the grain removing device 4 are measured. A load sensor 4A, a layer thickness sensor 4B for measuring the layer thickness of grains on the rocking shelf of the grain removal device 4, a monitor 20 for inputting set speeds V1 and V2, set torques T1 and T2, and a main shift lever. An angle sensor 25A for measuring the tilt angle of the 25, a changeover switch 25B for switching the transmission method provided on the main shift lever 25, and an angle sensor 26A for measuring the tilt angle of the auxiliary shift lever 26 are predetermined input interface circuits. It is connected via.

On the output side of the controller 15, a clutch 54 for connecting or disconnecting the output shaft 35 and the rotating shaft 55 and a tension arm 63 for tensioning and relaxing the tension of the belt 62 are connected via a predetermined output interface circuit. Has been done.

<First transmission method to transmit the rotation speed of the engine to the reaping device>
As shown in FIG. 6, in step S1, the processing unit 16 of the controller 15 reads the traveling speed V of the traveling device 2 input from the speed sensor 2A and proceeds to step S2.

In step S2, the processing unit 16 compares the traveling speed V with the set speed V1, and if the traveling speed V is lower than the set speed V1, the process proceeds to step S3, and the traveling speed V is higher than the set speed V1. In the case of, the process proceeds to step S6.

In the present embodiment, the traveling speed V and the set speed V1 are compared, but it is also possible to compare the tilt angle of the main speed change lever 25 input from the angle sensor 25A with the preset set angle.

In step S3, the processing unit 16 retracts the tension arm 63 from the belt 62 to relax the tension of the belt 62, and proceeds to step S4. As a result, the rotational speed of the engine is transmitted to the continuously variable transmission 27 via the input shaft 31, and the driving speed of the cutting device 3 can be accelerated or decelerated in synchronization with the traveling speed V of the traveling device 2, and the field can be increased or decreased. It is possible to efficiently cut the grain culm to be planted in.

In step S4, the processing unit 16 connects the clutch 54 and proceeds to step S5. As a result, the rotation speed of the engine transmitted to the output shaft 35 of the transmission 28 can be transmitted to the rotation shaft 55 to drive the cutting device 3.

In step S5, the processing unit 16 determines whether or not the changeover switch 25B for switching the drive speed of the cutting device 3 at high speed is input, and if it is determined that the changeover switch 25B is input, proceeds to step S6. If it is determined that the changeover switch 25B has not been input, the process returns to step S1.

In step S6, the processing unit 16 advances the tension arm 63 toward the belt 62 to tension the tension of the belt 62, and proceeds to step S7. As a result, the rotational speed of the engine is transmitted to the rotary shaft 55 via the belt 62 to drive the cutting device 3, so that the maximum output required for the continuously variable transmission 27 is reduced and the capacity is small. It can be replaced with the continuously variable transmission 27.

In step S7, the processing unit 16 disengages the clutch 54 and proceeds to step S8. As a result, it is possible to prevent the rotation speed of the engine transmitted to the rotation shaft 55 from being transmitted to the output shaft 35 and prevent the transmission 28 from being damaged.

In step S8, the processing unit 16 reads the traveling speed V of the traveling device 2 input from the speed sensor 2A and proceeds to step S9.

In step S9, the processing unit 16 compares the traveling speed V with the set speed V2, and if the traveling speed V is lower than the set speed V2, proceeds to step S10, and the traveling speed V is higher than the set speed V2. In the case of, the process returns to step S6. This makes it possible to prevent the states of the clutch 54 and the belt 62 from being frequently changed and improve the durability of the clutch 54 and the belt 62. The set speeds V1 and V2 can be changed according to the type of grain culm planted in the field. This makes it possible to adjust the switching of the transmission method of the cutting device 3 according to the type of grain culm planted in the field.

In step S10, the processing unit 16 determines the input status of the grain culm sensor 3A for measuring the grain culm in the reaping device 3, and there is no culm sensor conveyed to the culm removal device 4 in the reaping device 3. If the input value of 3A is OFF, the process returns to step S1, and if there is a grain culm conveyed to the grain removal device 4 in the reaping device 3 and the input value of the grain culm sensor 3A is ON, the process returns to step S6. As a result, the culm transported to the threshing device 4 can be quickly threshed.

<Second transmission method that transmits the rotation speed of the engine to the cutting device>
As shown in FIG. 7, in step S1, the processing unit 16 of the controller 15 reads the load torque T of the handling barrel shaft of the threshing device 4 input from the load sensor 4A, and proceeds to step S2.

In step S2, the processing unit 16 compares the load torque T and the set torque T1 and proceeds to step S3 when the load torque T is equal to or less than the set torque T1 and the torque is low, and the load torque T exceeds the set torque T1. In the case of high torque, the process proceeds to step S6.

In this embodiment, the load torque T and the set torque T1 are compared, but the layer thickness of the grains flowing down on the rocking shelf input from the layer thickness sensor 4B and the preset layer thickness are set. Can also be compared.

In step S3, the processing unit 16 retracts the tension arm 63 from the belt 62 to relax the tension of the belt 62, and proceeds to step S4. As a result, the rotational speed of the engine is transmitted to the continuously variable transmission 27 via the input shaft 31, and the driving speed of the cutting device 3 can be accelerated or decelerated in synchronization with the traveling speed V of the traveling device 2, and the field can be increased or decreased. It is possible to efficiently cut the grain culm to be planted in.

In step S4, the processing unit 16 connects the clutch 54 and proceeds to step S5. As a result, the rotation speed of the engine transmitted to the output shaft 35 of the transmission 28 can be transmitted to the rotation shaft 55 to drive the cutting device 3.

In step S5, the processing unit 16 determines whether or not the changeover switch 25B for switching the drive speed of the cutting device 3 at high speed is input, and if it is determined that the changeover switch 25B is not input, returns to step S1. If it is determined that the changeover switch 25B is input, the process proceeds to step S6.

In step S6, the processing unit 16 advances the tension arm 63 toward the belt 62 to tension the tension of the belt 62, and proceeds to step S7. As a result, the rotational speed of the engine is transmitted to the rotary shaft 55 via the belt 62 to drive the cutting device 3, so that the maximum output required for the continuously variable transmission 27 is reduced and the capacity is small. It can be replaced with the continuously variable transmission 27.

In step S7, the processing unit 16 disengages the clutch 54 and proceeds to step S8. As a result, it is possible to prevent the rotation speed of the engine transmitted to the rotation shaft 55 from being transmitted to the output shaft 35 and prevent the transmission 28 from being damaged.

In step S8, the processing unit 16 reads the load torque T of the handling barrel shaft of the threshing device 4 input from the load sensor 4A and proceeds to step S9.

In step S9, the processing unit 16 compares the load torque T and the set torque T2, and if the load torque T is equal to or less than the set torque T2 and the torque is low, the processing unit 16 proceeds to step S10, and the load torque T exceeds the set torque T2. In the case of high torque, the process returns to step S6. The set torques T1 and T2 can be changed according to the type of grain culm planted in the field. This makes it possible to adjust the switching of the transmission method of the cutting device 3 according to the type of grain culm planted in the field.

In step S10, the processing unit 16 determines the input status of the grain culm sensor 3A for measuring the grain culm in the reaping device 3, and there is no culm sensor conveyed to the culm removal device 4 in the reaping device 3. If the input value of 3A is OFF, the process returns to step S1, and if there is a grain culm conveyed to the grain removal device 4 in the reaping device 3 and the input value of the grain culm sensor 3A is ON, the process returns to step S6.

1 Aircraft frame 2 Traveling device 3 Cutting device 4 Threshing device 27 Continuously variable transmission 28 Transmission 31 Input shaft 35 Output shaft 54 Clutch 55 Rotating shaft 60 Pulley (first pulley)
61 Pulley (2nd pulley)
62 Belt 63 Tension arm V Traveling speed V1 Set speed (first set speed)
V2 set speed (second set speed)

The present invention relates to a combine equipped with a continuously variable transmission that accelerates / decelerates the traveling speed of a traveling device and the driving speed of a cutting device.

In the conventional combine, when the traveling speed of the traveling device is low, the cutting device is driven at a constant driving speed, and when the traveling speed of the traveling device is high, the driving speed of the cutting device is made to follow the traveling speed of the traveling device. Techniques for improving sex are known. (See Patent Document 1)

Japanese Unexamined Patent Publication No. 2000-203468

However, in the technique of Patent Document 1, the maximum output required for the continuously variable transmission becomes large, and it is necessary to mount a large continuously variable transmission, and the continuously variable transmission excessively occupies the space around the engine. I was afraid.

Therefore, a main object of the present invention is to provide a combine capable of suppressing an area occupied by a continuously variable transmission in a space around an engine while maintaining high work efficiency.

The present invention that solves the above problems is as follows.
That is, according to the first aspect of the present invention, the traveling device (2) is provided on the lower side of the machine frame (1) on which the engine is mounted, and the cutting device (3) is provided on the front side of the machine frame (1). In a combine equipped with a threshing device (4) behind the device (3),
When the traveling speed (V) of the traveling device (2) is a low speed equal to or lower than the first set speed (V1), the rotation speed output from the engine is a stepless transmission that accelerates or decelerates the rotation speed. It is transmitted to the traveling device (2) and the cutting device (3) via the (27) and the transmission (28) that accelerates / decelerates the rotation speed output from the stepless speed changer (27), and is transmitted to the traveling device. When the traveling speed (V) of (2) is higher than the first set speed (V1), the rotation speed output from the engine is the stepless transmission (27) and the transmission (28). The first pulley (60) transmitted to the traveling device (2) and supported by the input shaft (31) of the stepless transmission (27) and the rotating shaft (55) of the transmission (28). ) Is transmitted to the cutting device (3) via the belt (62) wound around the second pulley (61) supported by the transmission (28), and the output shaft (35) and the rotating shaft (55) of the transmission (28). ), And when the traveling speed (V) of the traveling device (2) is a low speed equal to or lower than the first set speed (V1), the clutch (54) is engaged. The tension arm (63) provided behind the belt (62) is retracted from the belt (62) to relax the tension of the belt (62), and the traveling speed (V) of the traveling device (2) is first set. When the speed is higher than the speed (V1), the clutch (54) is disengaged, the tension arm (63) is advanced toward the belt (62), and the tension of the belt (62) becomes tense. When the clutch (54) is disengaged, the traveling speed (V) of the traveling device (2) is higher than the first set speed (V1) and the first set speed (V1). In the case of a low speed between the second set speeds (V2), the clutch (54) is disengaged and the tension of the belt (62) is maintained . It is a combine.

The invention according to claim 2 is the combine according to claim 1 , wherein the first set speed (V1) and the second set speed (V2) can be set according to the seed pair of the grain culm planted in the field. Is.

According to the third aspect of the present invention, when the traveling speed (V) of the traveling device (2) is high and the cutting device (3) has a grain clutch to be transported to the threshing device (4). The combine according to claim 1 or 2 , wherein the clutch (54) is disengaged and the tension of the belt (62) is maintained.

The invention according to claim 4 is the combine according to any one of claims 1 to 3 , wherein the clutch (54) is a one-way clutch.

According to the invention according to claim 1, when the traveling speed (V) of the traveling device (2) is a low speed equal to or lower than the first set speed (V1), the rotation speed output from the engine is the rotation speed. It is transmitted to the traveling device (2) and the cutting device (3) via the continuously variable transmission (27) that accelerates and decelerates and the transmission (28) that accelerates and decelerates the rotation speed output from the continuously variable transmission (27). When the traveling speed (V) of the traveling device (2) is higher than the first set speed (V1), the rotation speed output from the engine is the continuously variable transmission (27) and the transmission (28). The first pulley (60) transmitted to the traveling device (2) and supported by the input shaft (31) of the continuously variable transmission (27), and the rotating shaft (55) of the transmission (28). It is transmitted to the cutting device (3) via the belt (62) wound around the second pulley (61) supported by the transmission (28) between the output shaft (35) and the rotation shaft (55) of the transmission (28). When the traveling speed (V) of the traveling device (2) is lower than the first set speed (V1), the clutch (54) is connected to the belt (62). The tension arm (63) provided at the rear is retracted from the belt (62) to relax the tension of the belt (62), and the traveling speed (V) of the traveling device (2) is higher than the first set speed (V1). If, the clutch (54) is disengaged, the tension arm (63) is advanced toward the belt (62), the tension of the belt (62) is tensioned, and the clutch (54) is engaged. When released, the traveling speed (V) of the traveling device (2) is between the first set speed (V1) and the second set speed (V2), which is lower than the first set speed (V1). In the case of, the clutch (54) is disengaged and the tension of the belt (62) is maintained , so that the maximum output required for the continuously variable transmission (27) is reduced. It can be replaced with a small continuously variable transmission (27), and the space around the engine occupied by the continuously variable transmission (27) and the transmission (28) can be suppressed. Further, when the traveling speed (V) of the traveling device (2) is low, the driving speed of the harvesting device (3) is made to follow the traveling speed (V) of the traveling device (2) to efficiently produce the grain culm. It can be cut and harvested.

Further , it is possible to easily form a change of the configuration for transmitting the output rotation of the engine to the cutting device (3).

Further, it is possible to prevent the states of the clutch (54) and the belt (62) from being frequently changed, and to improve the durability of the clutch (54) and the belt (62).

According to the invention of claim 2 , in addition to the effect of the invention of claim 1 , the first set speed (V1) and the second set speed (V2) are set to the seed pair of the culm planted in the field. Since it can be set accordingly, it is possible to adjust the switching of the transmission method of the cutting device (3) according to the type of grain culm planted in the field.

According to the invention of claim 3 , in addition to the effect of the invention of claim 1 or 2 , when the traveling speed (V) of the traveling device (2) is high, threshing is performed in the cutting device (3). If there is a grain to be transported to the device (4), the clutch (54) is disengaged and the tension of the belt (62) is maintained, so that the threshing device (4) is removed from the cutting device (3). ) Can be quickly threshed.

According to the invention of claim 4 , in addition to the effect of the invention of any one of claims 1 to 3 , the clutch (54) is a one-way clutch, so that the configuration of the clutch (54) can be simplified. Can be formed. Further, since the rotation speed of the engine transmitted to the rotation shaft (55) via the belt (62) is not transmitted to the output shaft (35), malfunction can be prevented.

It is a front view of a combine. It is a plan view of a combine. It is a left side view of the combine. It is explanatory drawing of the drive mechanism of a reaping device. It is a connection diagram of a controller. This is the first driving method of the reaping device. This is the second driving method of the reaping device.

As shown in FIGS. 1 to 3, the combine is provided with a traveling device 2 consisting of a pair of left and right crawlers traveling on the soil surface under the machine frame 1, and harvests grain culms in the field on the front side of the machine frame 1. A reaping device 3 is provided. Further, a threshing device 4 for threshing and sorting the grain culms harvested by the reaping device 3 is provided on the rear left side of the reaping device 3, and a control unit 5 on which the operator is boarded is provided on the rear right side of the reaping device 3. Has been done.

An engine room 6 for mounting an engine is provided on the lower side of the control unit 5, and a grain tank 7 for storing grains that have been threshed and sorted by the threshing device 4 is provided on the rear side of the control unit 5. , The grains stored in the Glen tank 7 are discharged to the outside by a discharge auger (not shown) connected to the Glen tank 7.

A front panel 10 is provided in front of the cockpit of the cockpit 5, and a side panel 11 is provided on the left side of the cockpit.

On the left side of the front panel 10, a touch panel type monitor that displays the traveling speed V and the like of the traveling device 2 and inputs the set speeds V1 and V2 of the traveling device 2 and the set torques T1 and T2 of the threshing device 4 to be described later. 21 is provided, and an operation lever 22 for operating the turning of the traveling device 2 and the raising and lowering of the cutting device 3 is provided on the right side.

A main shift lever 25 for operating a continuously variable transmission 27 that accelerates / decelerates the rotation speed and switches the rotation direction output from the engine is provided on the front portion of the side panel 11, and is provided on the rear side of the main shift lever 25. Is provided with an auxiliary shift lever 26 that operates a transmission 28 that accelerates / decelerates the rotational speed output from the continuously variable transmission 27. Further, the operating angle of the main shifting lever 25 is measured by an angle sensor 25A such as a potentiometer attached to the lower part of the main shifting lever 25, and the operating angle gutter of the auxiliary shifting lever 26 is located at the lower part of the auxiliary shifting lever 26. It is measured by an angle sensor 26A such as a mounted potentiometer. A limit sensor can be used instead of the angle sensors 25A and 26A.

When the main shift lever 25 is in the neutral position, the rotation speed output from the continuously variable transmission 27 becomes zero. When the main shift lever 25 is tilted forward from the neutral posture, the rotation direction output from the continuously variable transmission 27 becomes the same positive rotation as the rotation direction transmitted from the engine, and when the tilt angle of the front tilt posture becomes large. The rotation speed output from the continuously variable transmission 27 becomes faster, and the rotation speed output from the continuously variable transmission 27 becomes slower when the inclination angle of the front tilting posture becomes smaller. When the main shift lever 25 is tilted backward from the neutral posture, the rotation direction output from the continuously variable transmission 27 is the reverse rotation to the rotation direction transmitted from the engine, and the tilt angle of the rear tilt posture. When the value becomes large, the rotation speed output from the continuously variable transmission 27 becomes high, and when the inclination angle of the rear tilting posture becomes small, the rotation speed output from the continuously variable transmission 27 becomes slow.

When the auxiliary speed change lever 26 is tilted to a low speed position, the rotation speed transmitted from the continuously variable transmission device 27 is decelerated by the transmission 28 and transmitted to the traveling device 2 and the cutting device 3 to be tilted to the medium speed position. In that case, the rotational speed transmitted from the continuously variable transmission 27 is not accelerated or decelerated but is transmitted to the traveling device 2 and the cutting device 3, and when tilted to a high speed position, it is transmitted from the continuously variable transmission 27. The rotation speed is increased and transmitted to the traveling device 2 and the cutting device 3.

As shown in FIG. 4, the rotational speed output from the engine is transmitted to the input shaft 31 of the continuously variable transmission 27 via the pulley 30. The rotation speed transmitted to the input shaft 31 is output to the output shaft 32 after being accelerated or decelerated in the continuously variable transmission 27.

The rotation speed output to the output shaft 32 is transmitted to the gear 34 via the fixed gear 33 of the output shaft 32. The gear 34 is rotatably fixed to the output shaft 35. The rotation speed transmitted to the gear 34 is transmitted to the counter shaft 37 via the gear 36.

The rotation speed transmitted to the counter shaft 37 is transmitted to the gear 41 via the gear 40. The rotational speed transmitted to the gear 41 is transmitted to the output shaft 43 via the gear 42. The rotation speed transmitted to the output shaft 43 is transmitted to the traveling device 2 to drive the traveling device 2.

The rotation speed transmitted to the counter shaft 37 is interlocked with the gear 52 via the gear 50 or the gear 51 fixed to the counter shaft 37, and the rotation speed transmitted to the gear 52 is via a key (not shown). It is transmitted to the output shaft 35.

The gear 52 is formed by arranging gears having different pitch diameters. In the present embodiment, the gear 52 includes a gear 52A that engages with the gear 50 and a gear 52B that has a larger pitch diameter than the gear 52A that engages with the gear 51. Further, the gear 52 moves in the left-right direction on the output shaft 35 via the shifter 53 operated by the auxiliary shift lever 26. As a result, the length of the transmission 28 in the left-right direction can be suppressed, and the transmission device including the continuously variable transmission 27 and the transmission 28 can be miniaturized.

The rotation speed transmitted to the output shaft 35 is transmitted to the rotation shaft 55 via the clutch 54. The rotation speed transmitted to the rotating shaft 55 is transmitted to the cutting device 3 via a pulley 56 fixed to the rotating shaft 55 and a belt (not shown) to drive the cutting device 3. Thereby, the rotation speed transmitted to the output shaft 35 can be transmitted to the rotation shaft 55 with a simple structure, or the transmission can be cut off. As the clutch 54, a one-way clutch is used in which the rotational speed transmitted to the output shaft 35 can be transmitted to the rotary shaft 55, but the rotational speed transmitted to the rotary shaft 55 cannot be transmitted to the output shaft 35. It is preferable to do.

A pulley (“first pulley” in claim) 60 is provided on the left side of the pulley 30, and a pulley (“second pulley” in claim) 61 is provided on the right side of the pulley 56 on the rotating shaft 55. There is. A belt 62 is wound around the pulley 60 and the pulley 61, and a tension arm 63 for tensioning and relaxing the tension of the belt 62 is provided behind the belt 62. In this embodiment, the diameters of the pulley 60 and the pulley 61 are formed to be the same, but the speed increase ratio of the pulley 60 and the pulley 61 is the maximum speed increase ratio of the transmission device including the continuously variable transmission and the transmission. It is preferable to generate so as to be larger than.

When the traveling speed V of the traveling device 2 is set to a set speed (“first set speed” of claim) V1 or less , the tension arm 63 retracts from the belt 62 and the tension of the belt 62 relaxes. Then, the rotation speed output from the engine is transmitted to the cutting device 3 via the continuously variable transmission 27 and the transmission 28. Further, in this case, the clutch 54 is connected, and the rotation speed of the output shaft 35 is transmitted to the rotation shaft 55 via the clutch 54. As a result, the cutting device 3 can be driven in synchronization with the traveling device 2. It is possible to efficiently cut and harvest the grain culms planted in the field.

On the other hand, in the case of a high speed exceeding the set speed V1 in which the traveling speed V of the traveling device 2 is set, the tension arm 63 advances toward the belt 62, the tension of the belt 62 becomes tense, and the tension is output from the engine. The rotational speed is transmitted to the cutting device 3 via the pulley 60, the belt 62, and the pulley 61 without going through the continuously variable transmission 27 and the transmission 28. In this case, the clutch 54 is disconnected. As a result, the maximum output required for the continuously variable transmission 27 can be reduced and replaced with the small-capacity continuously variable transmission 27, and the transmission device including the continuously variable transmission 27 and the transmission 28 can be downsized. be able to.

<Controller connection diagram>
As shown in FIG. 5, the combine controller 15 is formed of a processing unit 16 including a CPU and the like, and a storage unit 17 including a ROM, RAM, a hard disk drive, a flash memory, and the like.

The processing unit 16 connects or disconnects the clutch 54 and the tension arm 63 as compared with the set speed V1 in which the traveling speed V of the traveling device 2 is set and the set torque T1 in which the load of the threshing device 4 is set. To move forward or backward with respect to the belt 62.

The storage unit 17 has a set speed V1 input via a monitor 20 provided on the front panel 10, a set speed V2 slower than the set speed V1 (“second set speed” in the claim), and a set torque. T1 and a set torque T2 smaller than the set torque T1 are stored.

On the input side of the controller 15, a speed sensor 2A for measuring the traveling speed V of the traveling device 2, a grain sensor 3A for measuring the presence or absence of a harvested grain in the cutting device 3, and a load of the grain removing device 4 are measured. A load sensor 4A, a layer thickness sensor 4B for measuring the layer thickness of grains on the rocking shelf of the grain removal device 4, a monitor 20 for inputting set speeds V1 and V2, set torques T1 and T2, and a main shift lever. An angle sensor 25A for measuring the tilt angle of the 25, a changeover switch 25B for switching the transmission method provided on the main shift lever 25, and an angle sensor 26A for measuring the tilt angle of the auxiliary shift lever 26 are predetermined input interface circuits. It is connected via.

On the output side of the controller 15, a clutch 54 for connecting or disconnecting the output shaft 35 and the rotating shaft 55 and a tension arm 63 for tensioning and relaxing the tension of the belt 62 are connected via a predetermined output interface circuit. Has been done.

<First transmission method to transmit the rotation speed of the engine to the reaping device>
As shown in FIG. 6, in step S1, the processing unit 16 of the controller 15 reads the traveling speed V of the traveling device 2 input from the speed sensor 2A and proceeds to step S2.

In step S2, the processing unit 16 compares the traveling speed V with the set speed V1, and if the traveling speed V is lower than the set speed V1, the process proceeds to step S3, and the traveling speed V is higher than the set speed V1. In the case of, the process proceeds to step S6.

In the present embodiment, the traveling speed V and the set speed V1 are compared, but it is also possible to compare the tilt angle of the main speed change lever 25 input from the angle sensor 25A with the preset set angle.

In step S3, the processing unit 16 retracts the tension arm 63 from the belt 62 to relax the tension of the belt 62, and proceeds to step S4. As a result, the rotational speed of the engine is transmitted to the continuously variable transmission 27 via the input shaft 31, and the driving speed of the cutting device 3 can be accelerated or decelerated in synchronization with the traveling speed V of the traveling device 2, and the field can be increased or decreased. It is possible to efficiently cut the grain culm to be planted in.

In step S4, the processing unit 16 connects the clutch 54 and proceeds to step S5. As a result, the rotation speed of the engine transmitted to the output shaft 35 of the transmission 28 can be transmitted to the rotation shaft 55 to drive the cutting device 3.

In step S5, the processing unit 16 determines whether or not the changeover switch 25B for switching the drive speed of the cutting device 3 at high speed is input, and if it is determined that the changeover switch 25B is input, proceeds to step S6. If it is determined that the changeover switch 25B has not been input, the process returns to step S1.

In step S6, the processing unit 16 advances the tension arm 63 toward the belt 62 to tension the tension of the belt 62, and proceeds to step S7. As a result, the rotational speed of the engine is transmitted to the rotary shaft 55 via the belt 62 to drive the cutting device 3, so that the maximum output required for the continuously variable transmission 27 is reduced and the capacity is small. It can be replaced with the continuously variable transmission 27.

In step S7, the processing unit 16 disengages the clutch 54 and proceeds to step S8. As a result, it is possible to prevent the rotation speed of the engine transmitted to the rotation shaft 55 from being transmitted to the output shaft 35 and prevent the transmission 28 from being damaged.

In step S8, the processing unit 16 reads the traveling speed V of the traveling device 2 input from the speed sensor 2A and proceeds to step S9.

In step S9, the processing unit 16 compares the traveling speed V with the set speed V2, and if the traveling speed V is lower than the set speed V2, proceeds to step S10, and the traveling speed V is higher than the set speed V2. In the case of, the process returns to step S6. This makes it possible to prevent the states of the clutch 54 and the belt 62 from being frequently changed and improve the durability of the clutch 54 and the belt 62. The set speeds V1 and V2 can be changed according to the type of grain culm planted in the field. This makes it possible to adjust the switching of the transmission method of the cutting device 3 according to the type of grain culm planted in the field.

In step S10, the processing unit 16 determines the input status of the grain culm sensor 3A for measuring the grain culm in the reaping device 3, and there is no culm sensor conveyed to the culm removal device 4 in the reaping device 3. If the input value of 3A is OFF, the process returns to step S1, and if there is a grain culm conveyed to the grain removal device 4 in the reaping device 3 and the input value of the grain culm sensor 3A is ON, the process returns to step S6. As a result, the culm transported to the threshing device 4 can be quickly threshed.

<Second transmission method that transmits the rotation speed of the engine to the cutting device>
As shown in FIG. 7, in step S1, the processing unit 16 of the controller 15 reads the load torque T of the handling barrel shaft of the threshing device 4 input from the load sensor 4A, and proceeds to step S2.

In step S2, the processing unit 16 compares the load torque T and the set torque T1 and proceeds to step S3 when the load torque T is equal to or less than the set torque T1 and the torque is low, and the load torque T exceeds the set torque T1. In the case of high torque, the process proceeds to step S6.

In this embodiment, the load torque T and the set torque T1 are compared, but the layer thickness of the grains flowing down on the rocking shelf input from the layer thickness sensor 4B and the preset layer thickness are set. Can also be compared.

In step S3, the processing unit 16 retracts the tension arm 63 from the belt 62 to relax the tension of the belt 62, and proceeds to step S4. As a result, the rotational speed of the engine is transmitted to the continuously variable transmission 27 via the input shaft 31, and the driving speed of the cutting device 3 can be accelerated or decelerated in synchronization with the traveling speed V of the traveling device 2, and the field can be increased or decreased. It is possible to efficiently cut the grain culm to be planted in.

In step S4, the processing unit 16 connects the clutch 54 and proceeds to step S5. As a result, the rotation speed of the engine transmitted to the output shaft 35 of the transmission 28 can be transmitted to the rotation shaft 55 to drive the cutting device 3.

In step S5, the processing unit 16 determines whether or not the changeover switch 25B for switching the drive speed of the cutting device 3 at high speed is input, and if it is determined that the changeover switch 25B is not input, returns to step S1. If it is determined that the changeover switch 25B is input, the process proceeds to step S6.

In step S6, the processing unit 16 advances the tension arm 63 toward the belt 62 to tension the tension of the belt 62, and proceeds to step S7. As a result, the rotational speed of the engine is transmitted to the rotary shaft 55 via the belt 62 to drive the cutting device 3, so that the maximum output required for the continuously variable transmission 27 is reduced and the capacity is small. It can be replaced with the continuously variable transmission 27.

In step S7, the processing unit 16 disengages the clutch 54 and proceeds to step S8. As a result, it is possible to prevent the rotation speed of the engine transmitted to the rotation shaft 55 from being transmitted to the output shaft 35 and prevent the transmission 28 from being damaged.

In step S8, the processing unit 16 reads the load torque T of the handling barrel shaft of the threshing device 4 input from the load sensor 4A and proceeds to step S9.

In step S9, the processing unit 16 compares the load torque T and the set torque T2, and if the load torque T is equal to or less than the set torque T2 and the torque is low, the processing unit 16 proceeds to step S10, and the load torque T exceeds the set torque T2. In the case of high torque, the process returns to step S6. The set torques T1 and T2 can be changed according to the type of grain culm planted in the field. This makes it possible to adjust the switching of the transmission method of the cutting device 3 according to the type of grain culm planted in the field.

In step S10, the processing unit 16 determines the input status of the grain culm sensor 3A for measuring the grain culm in the reaping device 3, and there is no culm sensor conveyed to the culm removal device 4 in the reaping device 3. If the input value of 3A is OFF, the process returns to step S1, and if there is a grain culm conveyed to the grain removal device 4 in the reaping device 3 and the input value of the grain culm sensor 3A is ON, the process returns to step S6.

1 Aircraft frame 2 Traveling device 3 Cutting device 4 Threshing device 27 Continuously variable transmission 28 Transmission 31 Input shaft 35 Output shaft 54 Clutch 55 Rotating shaft 60 Pulley (first pulley)
61 Pulley (2nd pulley)
62 Belt 63 Tension arm V Traveling speed V1 Set speed (first set speed)
V2 set speed (second set speed)

Claims (6)

A traveling device (2) is provided on the lower side of the machine frame (1) on which the engine is mounted, a cutting device (3) is provided on the front side of the machine frame (1), and a threshing device (3) is provided behind the cutting device (3). In the combine provided with 4)
When the traveling speed (V) of the traveling device (2) is a low speed equal to or lower than the first set speed (V1), the rotation speed output from the engine is a stepless transmission that accelerates or decelerates the rotation speed. It is transmitted to the traveling device (2) and the cutting device (3) via the (27) and the transmission (28) that accelerates / decelerates the rotation speed output from the stepless speed changer (27).
When the traveling speed (V) of the traveling device (2) is higher than the first set speed (V1), the rotational speed output from the engine is the continuously variable transmission (27) and the transmission ( The first pulley (60) transmitted to the traveling device (2) via the 28) and supported by the input shaft (31) of the continuously variable transmission (27), and the output shaft of the transmission (28). Transmission to the cutting device (3) via a belt (62) wound around a second pulley (61) supported by a rotating shaft (55) connected to the (35) via a clutch (54). The combine is characterized by the fact that it is configured to be used. When the traveling speed (V) of the traveling device (2) is low, the clutch (54) is engaged and a tension arm (63) provided behind the belt (62) is attached to the belt (62). The tension of the belt (62) is relaxed by retracting from
When the traveling speed (V) of the traveling device (2) is high, the clutch (54) is disengaged and the tension arm (63) is advanced toward the belt (62) to advance the belt. The combine according to claim 1, wherein the tension of (62) is tensioned. When the traveling speed (V) of the traveling device (2) is high, the traveling speed (V) of the traveling device (2) is lower than the first set speed (V1). The combine according to claim 2, wherein when the speed is higher than V2), the clutch (54) is disengaged and the tension of the belt (62) is maintained. The combine according to claim 3, wherein the first set speed (V1) and the second set speed (V2) can be set according to the seed pair of the grain culm planted in the field. When the traveling speed (V) of the traveling device (2) is high and there is a grain culm to be conveyed to the threshing device (4) in the cutting device (3), the clutch (54) is connected. The combine according to any one of claims 2 to 4, wherein is released and the tension of the tension of the belt (62) is maintained. The combine according to any one of claims 1 to 5, wherein the clutch (54) is a one-way clutch.

Images