JP2009178137A - Combine harvester - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a combine harvester capable of individually driving the conveying conveyer of a feeder house of a reaping part. <P>SOLUTION: This combine harvester equipped with a traveling part for traveling the same machine and a reaping part for reaping cereal culms while traveling by the traveling part is provided by installing a feeder house conveyer for conveying the reaped cereal culms at the reaping part. Since an electric motor for driving is provided at the feeder house conveyer, it is possible to drive the feeder house conveyer individually and reduce the number of components of driving system of the feeder house conveyer to simplify the driving system. Also, it is possible to improve workability in the case of maintaining the feeder house conveyer individually, etc. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a combine, and more particularly, to a structure of a cutting part of a general-purpose combine.

  Conventionally, as one form of combine, a harvesting unit that harvests cereals, a threshing unit that threshs cereals harvested by the harvesting unit, and an oscillating sorting unit that swings and sorts the grains threshed by the threshing unit, There is a thing equipped with the waste disposal part which processes the waste discharged from the above-mentioned threshing part.

  The cutting part includes a scraping reel that scrapes the cereal planted in the field, a cutting blade that shaves the root part of the cereal, and a feeder house conveyor described later while laterally feeding the cereal that has been cut by the cutting blade. And a feeder house conveyor for transporting the transported cereal to the threshing section.

And each drive part (a scraping reel, a cutting blade, a platform auger, a feeder house conveyor) of a cutting part receives motive power from an engine via a transmission belt, a transmission pulley, etc. (for example, refer to patent documents 1). .
Japanese Patent Application Laid-Open No. 07-050918

  However, since all the drive units of the cutting unit are configured to receive power from the engine, the drive units cannot be driven independently. For example, even when it is desired to drive a transport conveyor provided in a transport case of a feeder house conveyor, other scraping reels, cutting blades, and platform augers are driven simultaneously. Moreover, since the conventional cutting part is a structure which transmits motive power via a transmission belt and a transmission pulley in order to drive each drive part, many parts, such as the said transmission belt and a transmission pulley, are required.

  This invention was made in order to solve the said problem, and it aims at providing the combine which can drive the feeder house conveyor of a cutting part independently.

  The invention according to claim 1 is a combiner equipped with a traveling unit for traveling the machine and a harvesting unit for harvesting corn while traveling by the traveling unit, and a feeder for conveying the harvested cereal to the harvesting unit. The combine is characterized in that a house conveyor is provided and an electric motor for driving is provided on the feeder house conveyor.

  The invention described in claim 2 is provided with load detection means for detecting the load of the electric motor generated at the time of conveyance, and controls the vehicle speed of the machine according to the load detected by the load detection means. The combine according to claim 1.

  The invention according to claim 3 is characterized in that the feeder house conveyor stops the conveyance when the conveyance amount exceeds a predetermined reference amount. The combine according to claim 1 or 2, It is.

  The invention according to claim 4 is the combine according to any one of claims 1 to 3, wherein the feeder house conveyor is capable of emergency stop of its rotational drive. is there.

(1) In the present invention described in claim 1, in a combine equipped with a traveling unit for traveling the machine and a harvesting unit for harvesting cereal while traveling by the traveling unit, the harvested cereal is provided in the harvesting unit. Since the feeder house conveyor to be conveyed is provided and the feeder house conveyor is provided with an electric motor for driving, the feeder house conveyor can be driven independently, reducing the number of parts of the feeder house conveyor drive system. The drive system can be simplified. Moreover, workability | operativity, such as when maintaining a feeder house conveyor independently, improves.
(2) In the present invention according to claim 2, since the load detecting means for detecting the load of the electric motor generated at the time of conveyance is provided, the load corresponding to the amount of crop conveyed by the feeder house conveyor can be detected. . In addition, since the vehicle speed of the machine is controlled according to the load detected by the load detecting means, for example, when the amount of cereals conveyed by the feeder house conveyor is large, the vehicle speed of the traveling unit is reduced. If the amount is small, control is performed to increase the vehicle speed of the traveling unit, the amount of conveyance of the feeder house conveyor can be made constant, and the amount of conveyance of cereal can be stabilized.
(3) In the present invention according to claim 3, since the feeder house conveyor stops the conveyance when the conveyance amount exceeds a predetermined reference amount, the cereal grains are contained in the conveyance case of the feeder house conveyor. Generation | occurrence | production of the malfunction that it accumulates excessively and the feeder house conveyor stops functioning can be prevented beforehand. Moreover, since a conveyance amount can be stabilized and it can convey to a threshing part, the threshing operation | work which is a subsequent process can be stabilized.
(4) In the present invention according to claim 4, since the feeder house conveyor can be stopped in an emergency, the feeder house conveyor can be stopped in an emergency, and the feeder house conveyor can be stopped immediately to take a corrective action. can do.

  The combine according to the present embodiment includes, as a basic structure, a harvesting unit that harvests cereals, a threshing unit that threshs cereals harvested by the harvesting unit, and a selection unit that selects the grains threshed by the threshing unit. Equipped. And as a characteristic structure, each drive part of the said cutting part is driven with the electric motor.

  That is, an electric motor is connected to each drive unit of a scraping reel, a cutting blade, a platform auger, and a feeder house conveyor as each drive unit, and each drive unit is individually driven.

  Below, the combine in this embodiment is demonstrated, referring drawings.

  1 and 2 show a general-purpose combiner as a combine A provided with a threshing / sorting device according to the present embodiment, and the combine A is provided with a pair of left and right crawler type traveling units 3 at the lower part of the body 1. At the same time, the cutting unit 2 is attached to the front edge of the machine body 1 through a feeder house 4 serving as a transport unit, and the threshing unit 5 is disposed immediately after the feeder house 4. While the sorting unit 6 is disposed at a position immediately below the oscillating body 32, the squeezing processing unit 40 is disposed at the rear upper part of the rocking body 32 and immediately after the threshing unit 5.

  The combine A is a front portion of the machine body 1, and the operation unit 7 is disposed at a right side position of the feeder house 4, a position immediately after the operation unit 7, and a right side position of the threshing unit 5. The grain storage unit 8 is disposed at the top, and the prime mover unit 9 is disposed at a position immediately after the grain storage unit 8.

  Next, the structure of each part of the combine A will be described with reference to FIGS.

  As shown in FIG. 1, the traveling unit 3 has a traveling frame 25 attached to the lower part of the machine body 1, and a driving wheel 45 is interlocked and connected to the front end of the traveling frame 25. 46 is rotatably supported, and the crawler belt 26 is wound between the drive wheel 45 and the idle wheel 46. In the figure, 43 is a rolling wheel.

  As shown in FIGS. 1 and 2, the mowing unit 2 has a feeder house 4 attached to the front end of the machine body 1 so as to be pivotable up and down, and is conveyed in the conveyance case 60 formed by extending in the front-rear direction. A feeder house conveyor (hereinafter also referred to as “FH conveyor”) 14 is provided. The FH conveyor 14 extends horizontally by extending the driven shaft 23 in the left-right direction in the front part in the transport case 60, while extending the drive shaft 22 in the left-right direction in the rear part in the transport case 60. is doing. A feeder chain 24 is wound between the driven shaft 23 and the drive shaft 22.

  A platform 21 is connected to the front end of the feeder house 4, and a platform auger (hereinafter sometimes referred to as “PF auger”) 13, which is a lateral feed auger with an axis line in the left-right direction, is rotated in the platform 21. It is installed horizontally so that it can move. Further, a scraping reel 11 is provided on the upper front side of the platform 21. Further, on the lower surface side of the platform 21, a clipper-shaped cutting blade 12 extending in the left-right longitudinal shape is provided. Reference numeral 27 denotes a divider.

  In this way, the culm planted in the field is scraped with the reel 11, the root part of the culm is cut with the cutting blade 12, and then the culm that has been cut with the PF auger 13 is removed from the PF auger 13. They are gathered in a substantially central part and delivered to the FH conveyor 14 of the feeder house 4 at the rear. Then, the cereals collected by the PF auger 13 are conveyed to the rear threshing unit 5 through the FH conveyor 14. The mowing unit 2 and the feeder house 4 will be described later in detail.

  As shown in FIG. 1, the threshing unit 5 forms a handling chamber 44 at a position immediately after the conveying unit 4, a cylindrical handling cylinder 28 is provided inside the handling chamber 44, and a rotation axis is the length of the machine body 1. It is arranged in a state facing in the vertical direction. A spiral blade body 29 is attached to the peripheral wall of the main body of the handling cylinder 28. A concave 47 (reception net) is continuously stretched in the circumferential direction along the lower half peripheral surface of the handling cylinder 28 at a position directly below the handling cylinder 28.

  Thus, the cereals conveyed by the conveying unit 4 are moved from the front of the machine body 1 of the handling cylinder 28 by the action of the handling cylinder 28 in the threshing space formed between the handling cylinder 28 and the concave 47. The threshing process is carried out while being transported backward, and grains, cereals, swarf, etc. pass through the respective concaves 47 due to their own weight and fall to the lower sorting section 6, while relatively large spills and the like are spilled behind. It is transferred to the processing unit 40.

  As shown in FIG. 1, the sorting unit 6 is provided with a swinging body 32 at a position directly below the handling cylinder 28 so as to swing up and down via a swinging mechanism 33. 35 is the first grain receiver that extends in the left-right direction and receives the first grain, 37 is the second grain receiver that extends in the left-right direction and receives the second grain, and 41 is the Karatsu. 42 is a pre-cooling fan.

  The oscillating body 32 includes a feed pan 48 positioned directly below the handling cylinder 28, a front chaff sheave 30 with an adjustable grain leakage amount, a grain sheave 49 provided below the front chaff sheave 30, and the A rear chaff sheave 31 is arranged behind the front chaff sheave 30 so that the amount of grain leakage can be adjusted.

  And the first conveyor 36 extending in the left-right direction is arranged in the first grain receptacle 35, and the lower end portion of the cereal conveyor (not shown) extending in the vertical direction on the left end portion of the same number conveyor 36 In the meantime, the upper end of the cereal conveyor is connected to the above-described grain storage unit 8, and the first grain in the first grain receptacle 35 is the first conveyor 36 → the cereal conveyor → It is made to convey to the grain storage part 8. FIG.

  In addition, a second conveyor 38 extending in the left-right direction is disposed in the second grain receiving box 37, and the rear end of a reducing conveyor (not shown) extending in the front-rear direction at the left end of the second conveyor 38. In the meantime, the front end of the reduction conveyor is connected to the handling chamber 44, and the second grain in the second grain receptacle 37 is returned to the sorting unit 6 and sorted again. I am doing so.

  In this way, the threshing that has been threshed by the handling cylinder 28 is received by the feed pan 48, and the grain and swarf are supplied to the front chaff sheave 30 from the feed pan 48, and coarsely sorted by the front chaff sheave 30, The grain and swarf leaked from the front side chaff sheave 30 are supplied to the grain sieve 49, and the grain and swarf are supplied to the grain sieve 49. The grain sieve 49 finely sorts and the grain sieve 49 leaks from the grain sieve 49. The grain is received by the first grain receiver 35 as the first grain.

  Then, the grain and sawdust transferred from the front chaff sheave 30 to the rear chaff sheave 31 are roughly sorted by the rear chaff sheave 31, and the grain leaked from the rear chaff sheave 31 is used as the second grain. It is made to receive in the grain receiving receptacle 37.

  In addition, the Kara 41 can be disposed at the front position of the first grain receiving rod 35 so that air can be blown from the Kara 41 under the swinging body 32. Specifically, the sorting air can be blown from the lower side of the front side chaff sheave 30 to the upper side of the tang 41.

  As shown in FIGS. 1 and 6, the waste disposal unit 40 is provided with a rear conveyance beater (not shown) at a position immediately behind the handling cylinder 28 of the threshing unit 5, and at a rear position of the rear conveyance beater. An evacuation cutter 66 is provided. Then, the waste after being threshed by the threshing unit 5 is transported to the waste cutter 66 by the transport action of the rear transport beater, and the waste is shredded by the waste cutter 66 and then discharged to the outside of the machine body 1. Like to do.

  The operating unit 7 has a substantially rectangular box-shaped cabin 50 disposed on the upper right side (plan view) of the front end of the fuselage 1, a seat 81 is disposed in the center rear portion of the cabin 50 in plan view, A front column 76 is disposed at a front position, a steering wheel 77 is disposed at an upper end portion of the front column 76, and a shift column 79 is disposed at a left side position of the front column 76 to operate the shift column 79. A portion 80 is provided.

  The grain storage unit 8 has a grain tank 58 disposed on the right side of the handling cylinder 28 provided in the threshing unit 5 described above, and the grain storage unit 8 provided in the sorting unit 6 is provided in the grain tank 58. The urn 35 is connected to and communicated through a cereal conveyor (not shown), and a horizontal carry-out screw conveyor (not shown) is horizontally mounted on the lower right side in the Glen tank 58 with the axis line in the front-rear direction. A vertical carry-out screw conveyor (not shown) having a lower end portion connected to the rear end portion of the horizontal carry-out screw conveyor 56 is disposed at the right side position of the prime mover unit 9 with the axis line directed in the vertical direction. A discharge auger 10 having a rear end portion connected to the upper end portion of the conveying screw conveyor is extended forward, and can turn and rotate up and down around the rear end portion. Reference numeral 13 denotes a discharge port of the discharge auger 10.

  In this way, the first grain sorted by the sorting unit 6 can be conveyed into the Glen tank 58 via the cereal conveyor and stored in the Glen tank 58, while The first grain stored in can be discharged to the outside of the machine body 1 from a discharge port (not shown) through a screw conveyor for horizontal carrying out → a screw conveyor for vertical carrying out → a discharge auger 10.

  The prime mover unit 9 has an engine E disposed at the left front portion of the machine body 1 and is linked to each power mechanism unit such as a mission (not shown) via a transmission mechanism (not shown). . And by driving the engine E, each power mechanism part operates in conjunction.

  In the configuration as described above, the gist of the present invention resides in that each drive unit of the cutting unit 2 is driven by the electric motors 101 to 104 as shown in FIGS. 3 and 4. Hereinafter, each structure of the scraping reel 11, the cutting blade 12, the PF auger 13, and the FH conveyor 14 which are each drive part of the cutting part 2 is demonstrated in detail.

  First, the structure of the scraping reel 11 will be described.

  The scraping reel 11 is disposed above the platform 21 as shown in FIG. That is, a base end portion of a pair of left and right reel support arms 19 extending in the front-rear direction is attached above the platform 21, and the reel support shaft 15 is horizontally mounted in the left-right width direction of the machine body 1 between the front end portions. ing. Six reel forming arms 16 extending in the radial direction are provided on the left and right ends of the reel support shaft 15.

  Further, the leading ends of the reel forming arms 16 are connected by a connecting piece 17. Further, a tine bar 20 extending in the left-right width direction is installed between the front ends of the reel forming arms 16 facing left and right. A plurality of scraping tines 18 are hung from each tine bar 20 at a predetermined interval.

  The scraping reel 11 is configured to be adjustable in vertical position and longitudinal position by a reel lifting / lowering hydraulic cylinder and a reel front / rear adjustment hydraulic cylinder according to the lying state and growing state of the cereal.

  The position of the scraping reel 11 can be adjusted by the control unit 34 provided in the cabin of the operating unit 7 through the reel raising / lowering hydraulic cylinder and the reel front / rear adjusting hydraulic cylinder which are the adjusting actuators. It has become.

  In such a configuration, the scraping reel 11 in the present embodiment, as shown in FIGS. 3 and 4, interlocks the drive shaft of the reel electric motor 101 with the reel spindle 15 of the scraping reel 11, The reel is driven by the rotation of the drive shaft of the electric motor 101 for reels.

  As long as the reel electric motor 101 rotates the reel spindle 15 of the scraping reel 11 at a predetermined rotation speed, its size, torque capacity, maximum rotation speed, and the like are not limited. Electric power for the electric motors 101 to 104 is supplied through a harness from a generator 72 or a battery 73 described later. In addition, a drive command to the reel electric motor 101 is disposed at a predetermined position of the machine body 1 by appropriately operating an operation switch (not shown) and a wireless remote controller (not shown) provided in the operation unit 7. It can be operated via the cutting unit controller 100. In addition, the platform 21 is provided with a reel emergency operation SW 123 which is an emergency drive / stop switch, and the rotation operation of the scraping reel 11 is emergency stopped by the emergency operation SW 123 or the operation switch or the wireless remote controller. To be able to.

  Next, the structure of the cutting blade 12 will be described.

  As shown in FIG. 3, the cutting blade 12 is disposed in front of the PF auger 13 and below the scraping reel 11. The cutting blade 12 includes a fixed blade 51 that extends in the left-right direction, and a reciprocating sliding blade 52 that reciprocates in the left-right direction on the fixed blade 51. In this way, the fixed blade 51 and the reciprocating sliding blade 52 cooperate to cut the cereal grains that have been planted.

  In such a configuration, the cutting blade 12 according to the present embodiment is provided with a cutting blade drive case (not shown) on the right side wall of the platform 21, as shown in FIG. An electric motor 102 is disposed, and the rotational power of the cutting blade electric motor 102 is transmitted to the cutting blade 12 via the link mechanism 55. In this way, the reciprocating sliding blade 52 of the cutting blade 12 is reciprocated in the left-right direction to cut the cereal stock. The link mechanism 55 converts the rotation of the drive shaft of the cutting blade electric motor 102 into the reciprocating motion of the reciprocating sliding blade 52.

  As an option, a secondary mower sub-cutting blade (not shown) can be disposed behind the cutting blade 12. Then, similarly to the cutting blade 12, the rotational power of the cutting blade electric motor 102 can be transmitted to the auxiliary cutting blade via a link mechanism or the like.

  Next, the structure of the platform 21 will be described.

  The platform 21 includes a pair of left and right auger support walls 70 and is disposed between the raking reel 11 and the FH conveyor 14. As shown in FIG. 2, the PF auger 13 is horizontally mounted in the left-right width direction of the body 1 between a pair of left and right auger support walls. The PF auger 13 has a spiral blade body 54 attached to the outer peripheral portion of a cylindrical main body 71 extending in the left-right direction. Further, a scraping finger 53 is provided on the outer peripheral portion of the main body so as to be able to appear and disappear in the radial direction.

  In such a configuration, as shown in FIG. 3, the PF auger 13 is driven by the PF auger electric motor 103. That is, the PF auger electric motor 103 is disposed on the platform 21 that supports the PF auger 13, and the drive shaft of the PF auger electric motor 103 and the PF auger support shaft are connected. That is, the PF auger 13 is driven to rotate.

  Next, the structure of the FH conveyor 14 will be described.

  As shown in FIGS. 3 and 4, the FH conveyor 14 is disposed behind the platform 21. The FH conveyor 14 is provided in a house body 60 formed in a cylindrical shape extending in the front-rear direction, and the front end of the house body 60 is communicated with the rear portion of the platform 21.

  The FH conveyor 14 has a driven side shaft 23 that extends in the left-right direction at the front portion in the house body 60, and a drive-side shaft 22 that extends in the left-right direction in the rear portion in the house body 60. A feeder chain 24 is wound around the shafts 22 and 23 via a sprocket. And the conveyance path | route which conveys a grain candy between the lower inner surface of the house main body 60 and the lower part of the conveyance conveyor 57 is formed. In this way, the cereals harvested through the transport path are transported from the harvesting unit 2 to the threshing unit 5.

  In such a configuration, as shown in FIG. 3, the FH conveyor 14 in the present embodiment is configured such that the drive shaft of the FH conveyor electric motor 104 is linked to the drive side shaft 22, and the FH conveyor electric motor 104 performs FH. The conveyor 14 is driven.

  Next, the configuration of the electric motor and its peripheral devices in each drive unit will be described with reference to FIG. As shown in FIG. 5, electric power is supplied to the electric motors 101 to 104 in each drive unit from a battery 73 and a generator 72 (alternator) as drive sources. In addition, a generator 72 is connected to the battery 73, and an engine E is connected to the generator 72. Therefore, during normal travel, the shaft portion of the generator 72 is rotated by the rotation of the shaft portion of the engine E, electric power is generated by the generator 72, and the electric power is supplied to the electric motors 101 to 104.

  Further, when the engine E is stopped, power is supplied from the battery 73. During normal travel, the battery 73 is charged with electric power from the generator 72. In this way, stable electric power is supplied from the generator 72 to the reel electric motor 101 during normal running, and electric power is supplied from the battery 73 to the reel electric motor 101 when the engine E is stopped.

  And the electric motor 101 for reels can be driven by control from the cutting unit controller 100 provided with a CPU. The cutting unit controller 100 is disposed at a predetermined location of the machine body 1. The reaping unit controller 100 receives the operation command operated by the operation unit 80 disposed in the operation unit 7 and drives the scraping reel 11 by the reel electric motor 101 via the reel electric motor driver 141. And control the vehicle speed.

  As with the driving of the scraping reel 11, each control of the cutting blade 12, the PF auger 13, and the FH conveyor 14 is performed by the cutting unit controller 100 via the motor drivers 141 to 144. Further, the electric power to the electric motor 102 for cutting blade, the electric motor 103 for PF auger, and the electric motor 104 for FH conveyor is supplied from the generator 72 and the battery 73 in the same manner as the electric motor 101 for reel.

  Next, the power transmission of the combine A will be described with reference to FIG.

  Power from the engine E is transmitted for driving the rotor of the threshing unit 5 through the threshing clutch 61. The power from the engine E is transmitted for driving the Kara 41, the rocking body 32, the pre-cooling fan 42, the first conveyor 36, the second conveyor 38, and the second vertical conveyor 67 arranged in the sorting unit 6. The Further, the power from the engine E is transmitted to the lower conveyor 63, the vertical conveyor 64, and the discharge conveyor 65 disposed in the grain storage unit 8 via the discharge auger clutch 69. Further, it is also transmitted to the HST 62 of the traveling unit.

  Conventionally, the power from the engine E is transmitted to each drive unit of the cutting unit 2 via a plurality of transmission belts and pulleys. On the other hand, the combine A in this embodiment provided the electric motor in each drive part of the cutting part 2, and each drive part was driven individually with each electric motor. That is, as shown in FIG. 6, the drive shaft of the electric motor is connected to the reel spindle 15 of the scraping reel 11 to transmit the power of the electric motor to the scraping reel 11. Thereby, while being able to delete components, such as a transmission belt and a transmission pulley which were used conventionally, the drive mechanism of the cutting part 2 can be simplified.

  As with the scraping reel 11, the driving force of the electric motor is transmitted to the driving shaft of each driving unit for the cutting blade 12, the PF auger 13, and the FH conveyor 14.

  Next, drive control of each drive unit will be described in detail. First, the main process of the harvesting unit 2 of the combine A will be described with reference to FIG.

  As shown in FIG. 7, in the main process, first, the engine E is started (step S101), and activation processing of each drive unit of the cutting unit 2 is performed (step S102). The activation process will be described later in detail. Next, when the machine body 1 is in the running state, a cutting process is performed in each drive unit of the cutting unit 2 (steps S103 to S106). When the cutting process is completed and the engine E is stopped (step S107), the cutting unit 2 is stopped (step S108). Hereinafter, a specific flow of the main process will be described in detail.

  The activation process can be performed in the following order. As shown in FIG. 8, first, the FH conveyor electric motor 104 is activated to drive the FH conveyor 14 (step S201). Next, the PF auger electric motor 103 is activated to drive the PF auger 13 (step S202). Thereafter, the cutting blade electric motor 102 is activated to drive the cutting blade 12 (step S203). Finally, the reel electric motor 101 is activated to drive the scraping reel 11 (step S204). Thus, since it drives in order of FH conveyor 14-> PF auger 13-> cutting blade 12-> rake reel 11, crops are less likely to get tangled in the middle of each drive unit.

  The stop process can be performed in the following order. As shown in FIG. 9, first, the reel electric motor 101 is stopped, and the driving of the scraping reel 11 is stopped (step S301). Next, the electric motor 102 for cutting blade is stopped, and the driving of the cutting blade 12 is stopped (step S302). Thereafter, the PF auger electric motor 103 is stopped to stop the driving of the PF auger 13 (step S303). Finally, the driving of the FH conveyor electric motor 104 is stopped, and the driving of the FH conveyor 14 is stopped (step S304). As described above, since the driving is stopped in the order of the scraping reel 11 → the cutting blade 12 → the PF auger 13 → the FH conveyor 14, the crops harvested by each driving unit are less likely to remain.

  Next, the reel driving process of the scraping reel 11 will be described with reference to FIG.

  As shown in FIG. 10, in the reel driving process, when the combine A according to this embodiment is run in the field, the scraping reel 11 is driven by the rotation of the drive shaft of the electric motor 101 for reels to scrape the crop. become.

  In the case of an upright rod, a large load is not applied, and the drive torque of the electric motor is small. Get higher. In addition, in order to cause lodging, the reel tine becomes a trajectory of the ground thread, and it may dig into the soil or scratch the stone. The load can be detected by replacing such fluctuations in the drive torque with the current value of the electric motor.

  That is, when the crop is scraped with the scraping reel 11, a load is generated when the reel causes the crop, and the current flowing through the electric motor 101 for reel driving the scraping reel 11 is detected (step S401). The current is detected by a reel current detector 155 as load detecting means.

  When the amount of crops to be scraped by the scraping reel 11 is large, the load on the drive shaft for rotating the scraping reel 11 increases, and a driving torque is required. Therefore, the current flowing through the reel electric motor 101 increases. Become. On the other hand, when the amount of the crop scraped by the scraping reel 11 is small, the current flowing through the reel electric motor 101 is small. Then, in accordance with the detected current value, the vehicle speed is controlled to select so-called vehicle speed tuning or constant vehicle speed (step S402). When the vehicle speed is synchronized, the vehicle speed synchronization mode is set by turning on the reel vehicle speed control SW 131 provided in the operation unit 80 of the driving unit 7. When the reel vehicle speed control SW 131 is not turned on, the vehicle speed is constant.

  In the vehicle speed tuning, the cutting unit controller 100 controls the vehicle speed controller 159 to reduce the vehicle speed when the crop load is large and the current flowing through the reel electric motor 101 is large. On the other hand, when the crop load is small and the current flowing through the reel electric motor 101 is small, the vehicle speed controller 159 performs control to increase the vehicle speed (step S403).

  The vehicle speed control is performed, for example, by controlling the number of revolutions of the engine E, braking control of the brake mechanism, or the like. In this way, the traveling speed can be controlled while controlling the rotation of the scraping reel 11 according to the crop.

  And, when the worker throws the crop into the platform 21 and supplies it without rake in with the rake reel 11, or in an emergency, it is disposed in the driving unit 7, the wireless remote controller, or the platform 21. The emergency stop SW 123 is activated (step S404). As a result, it is possible to stop driving only the scraping reel 11 (step S405). Conventionally, the scraping reel 11 cannot be stopped alone, and the throwing operation is performed while the scraping reel 11 is driven. In the present embodiment, the throwing operation can be performed in a state where the scraping reel 11 is stopped alone, so that it is possible to reduce the risk during the operation.

  Further, when the vehicle speed is constant with respect to the vehicle speed synchronization, the vehicle speed is kept constant regardless of the crop load. When the vehicle speed is not synchronized, it is selected whether or not the driving reel 11 is driven with manual priority (step S406). That is, the operator selects whether or not to manually perform the rotation control of the scraping reel 11 while operating the operation unit 80 on the seat 81 of the driving unit 7.

  When the manual operation is selected, the operator inputs the manual operation of the reel manual operation SW 121 for manual operation in the operation unit 80. After inputting the reel manual operation SW 121, the rotation speed of the scraping reel 11 requested by the operator can be manually changed by the scraping reel manual speed setting device 122 disposed in the operation unit 80 ( Step S407). At that time, the reel electric motor 101 coupled to the scraping reel 11 realizes a rotational shift with a minimum of manual operation and time lag.

  Thereafter, similarly to the steps S404 and S405, it is determined whether or not an emergency stop has occurred (step S408), and an emergency stop process (step S409) is performed.

  Next, the driving process of the cutting blade 12 will be described with reference to FIG.

  Specifically, as shown in FIG. 11, the combine A is run in the field, and the cutting blade 12 is driven along with the driving of the scraping reel 11. When the cutting blade 12 cuts the crop, a predetermined load is applied to the cutting blade 12. For example, the current flowing through the electric motor is detected by the cutting blade current detector 156 as load detecting means (step S501).

  In the combine A, the so-called “stretching” that cuts along the line direction at the time of planting, and the so-called “lateral cutting” that cuts in the direction substantially orthogonal to the line direction at the time of planting. Can be done. And when load changes largely compared with the case of a row cutting, the cutting part controller 100 determines with the time of a horizontal cutting (process S502).

  In the case of row cutting, the cutting operation can be performed by the cutting blade 12 without greatly changing the vehicle speed (step S503). After that, according to the amount of load to be trimmed, whether to synchronize with the vehicle speed or to trim at a constant speed is selected by the cutting blade vehicle speed control SW 132 (step S504).

  In the case of vehicle speed tuning, the vehicle speed is controlled in accordance with the current flowing through the cutting blade electric motor 102 (step S505). When the crop load is large and the current flowing through the cutting blade electric motor 102 is large, the vehicle speed controller 159 reduces the vehicle speed. On the other hand, when the load on the crop is small and the current flowing through the electric motor 102 for cutting blade is small, the vehicle speed controller 159 increases the vehicle speed.

  Then, when the cutting blade 12 is damaged when the crop is cut with the cutting blade 12 (step S506), the emergency stop for the cutting blade disposed in the operation unit 7, the wireless remote controller, and the platform 21 is performed. The SW 124 is pressed to urgently stop the driving of the cutting blade 12 (step S507).

  On the other hand, at the time of horizontal cutting, the vehicle speed controller 159 causes the combine A to travel at a lower vehicle speed than at the time of cutting (step S508). In this way, it is possible to prevent the cutting blade 12 from being damaged during the horizontal cutting. Then, also during the horizontal cutting, the cutting blade is selected as to whether the vehicle speed is synchronized or whether the cutting is performed at a constant speed according to the amount of load to be cut (step S509). In the case of vehicle speed synchronization, the vehicle speed is controlled according to the crop load (step S510). Thereafter, it is determined whether or not the cutting blade 12 is broken (step S511). If the cutting blade 12 is damaged, the cutting blade emergency stop process is performed by the cutting blade emergency stop SW 124 provided in the operating unit 7, the wireless remote controller, and the platform 21 (step S512).

  Next, a method for driving the PF auger 13 will be described with reference to FIG.

  As shown in FIG. 12, the PF auger 13 disposed in the platform 21 is driven while the combine A is traveling in the field. The rotation speed of the PF auger 13 can be changed according to the crop. When the PF auger 13 takes in the crop, a predetermined load is applied to the PF auger 13. For example, the current flowing through the PF auger electric motor 103 is detected from the load using the PF auger current detector 157 (step S601).

  Next, the amount of load applied to the PF auger 13 varies depending on the amount of crop to be taken in. Then, the PF auger vehicle speed control SW 133 selects whether to control the vehicle speed in accordance with the load or to control the vehicle speed regardless of the load (step S602).

  When the vehicle speed is synchronized according to the load, the vehicle speed controller 159 reduces the vehicle speed when the crop load is large and the current flowing through the PF motor is large. On the other hand, when the crop load is small and the current flowing through the PF motor is small, the vehicle speed controller 159 increases the vehicle speed (step S603).

  Then, when the amount of the crop to be taken in is large when the crop is taken in by the PF auger 13 and the cereal wraps around the PF auger 13 (step S604), a warning process is performed (step S605). The rotation of the PF auger 13 is stopped by the emergency stop SW 125 for the PF auger provided on the operating unit 7, the wireless remote controller, and the platform 21 (step S606).

  Thereafter, whether or not to reversely rotate the PF auger 13 is selected (step S607). In the case of reverse rotation, for example, an input of a reverse switch (not shown) provided on the side of the machine body 1 is performed. Thus, the PF auger 13 is reversely rotated (step S608). Thereby, the cereal wrap around the PF auger 13 can be removed.

  In addition, when reverse rotation processing is performed, the PF auger 13 is reversely operated for a certain short time, for example, for 1 to 2 seconds, so that the wound cereal is returned to the original state and the PF auger 13 is reversely rotated for a long time. The loss of the grain which occurs sometimes can be suppressed as much as possible.

  Next, a method for driving the FH conveyor 14 will be described with reference to FIG.

  As shown in FIG. 13, the combine A is run in the field, and the driving process of the transport conveyor 57 in the FH conveyor 14 is performed. A predetermined load is applied to the FH conveyor 14 when the FH conveyor 14 conveys the crop to the threshing unit 5. For example, the current flowing through the electric motor 104 for the FH conveyor is detected from the load using the feeder current detector 158 (step S701).

  The amount of the load of the FH conveyor 14 varies depending on the amount of cereals to be conveyed. Then, the operator selects whether to control the vehicle speed in accordance with the crop load in the FH conveyor 14 or to keep the vehicle speed constant regardless of the load by the FH vehicle speed control SW 134 (step S702).

  When the vehicle speed is synchronized according to the load, the vehicle speed of the airframe 1 is decreased by the vehicle speed controller 159 when the crop load is large and the current flowing through the electric motor 104 for the FH conveyor is large. On the other hand, when the crop load is small and the current flowing through the FH conveyor electric motor 104 is small, the vehicle speed controller 159 increases the vehicle speed (step S703). In this way, the vehicle speed can be controlled to make the amount of cereals conveyed from the FH conveyor 14 to the threshing section 5 as a subsequent process constant.

  Moreover, if the quantity of the grain mash to convey increases, a load will increase to the handling cylinder 28 of the threshing part 5 which is a subsequent process. Therefore, the load on the cereal barrel to be conveyed is detected, the load on the handling cylinder 28 is predicted, and the rotational speed of the handling cylinder 28 is controlled (step S704). That is, when the crop load is large and the current flowing through the FH conveyor electric motor 104 is large, the rotational speed of the handling cylinder 28 is decreased. On the other hand, when the crop load is small and the current flowing through the FH conveyor electric motor 104 is small, the rotational speed of the handling cylinder 28 is increased (step S705). In this manner, the rotor overload due to the increase in the amount of cereal in the threshing unit 5 can be reduced, and the sorting flow rate can be made constant in the sorting unit 6.

  In addition, if the waste stays in the FH conveyor 14 or if the waste becomes tangled with the driving side shaft or the driven side shaft, an excessive load is applied to the electric motor 104 for the FH conveyor. That is, an excessive current flows through the electric motor 104 for the FH conveyor. It is detected that an excessive current has flowed (step S706), and a warning is notified to the worker (step S707). Then, the feeder chain 24 of the FH conveyor 14 is stopped by the FH emergency stop SW 126 disposed on the operating unit 7, the wireless remote controller, and the platform 21 (step S708). Thereafter, it is selected whether or not the feeder chain 24 is reversely rotated (step S709). If the feeder chain 24 is reversely rotated, reverse rotation processing is performed to discharge tangled crops (step S710).

  Next, the maintenance mode will be described.

  Conventionally, the cutting unit 2 transmits power from the engine E by means of a transmission belt and a pulley. Therefore, for example, only the scraping reel 11 cannot be driven alone among the driving units. Therefore, the combine A in the present embodiment can perform maintenance by individually operating each drive unit by disposing the electric motors 101 to 104 in each drive unit.

  For example, operation switches 127 to 130 for the maintenance mode are provided in the operation unit 80 of the driver's seat, and when the operator inputs the operation switches 127 to 130 for the maintenance mode, the normal travel / work mode is switched to the maintenance mode. It can be performed. The maintenance mode can be set regardless of when the engine E is driven or stopped.

  In addition, each drive unit can be driven by a wireless remote controller (not shown) so that an operator can perform maintenance while getting off the machine body 1. That is, operation switches 127 to 130 for the drive units are provided to operate the drive units on the operation panel of the wireless remote controller, and the operator sets the maintenance mode by turning on the operation switches 127 to 130. The maintenance of each drive unit can be performed.

  Further, the platform 21 is provided with operation switches 127 to 130 for maintenance of each drive unit, and an operator can set the maintenance mode by turning on each operation switch 127 to 130 to perform maintenance of each drive unit. it can. In this way, the setting to the maintenance mode can be performed from each operation switch of the driving unit 7, the wireless remote controller, and the platform.

  The operation switches 127 to 130 for each maintenance of each drive unit can operate each drive unit for a time when the switch is continuously pressed. For example, when the tine bar 20 of the scraping reel 11 is changed, the scraping reel 11 can be rotated at a low speed and stopped at an arbitrary position by continuously pressing the reel maintenance SW 127 for several seconds.

  In addition, each tine bar 20 of the scraping reel 11 is provided with a soybean reel slat (semi-transparent cover) that suppresses head loss during soybean cutting. It is also effective to attach the soybean reel slats while rotating.

  Furthermore, it can be used when searching for a broken portion of the joint link of the feeder chain 24 in the FH conveyor 14 while inputting the maintenance SW 130 for the feeder house.

  Next, management of the frequency of a plurality of electric motors will be described.

  In the combine A in this embodiment, the frequency of the plurality of electric motors is managed by the reaper controller 100 by a program. Here, the frequency of the electric motor is the number of times a phenomenon such as electric vibration (electromagnetic wave or vibration current) is repeated per unit time (1 second in the case of Hz). In this way, the resonance point of a component that is easily affected by the frequency of the adjacent cover is input in advance, and the resonance point is avoided to prevent damage to the machine or maintain / improve the durability of the component. . As a program, in order to avoid working for a long time at a dangerous rotational speed, for example, ± 20% deceleration / acceleration is avoided prior to all controls.

It is a side view which shows the whole structure of the combine in embodiment of this invention. It is a top view which shows the whole structure of the combine in embodiment of this invention. It is a side view which shows the structure of the harvesting part of the combine in embodiment of this invention. It is a top view which shows the structure of the harvesting part of the combine in embodiment of this invention. It is a power transmission diagram which shows the structure of the power transmission of the combine in embodiment of this invention. It is a block diagram which shows the hardware constitutions of the combine in embodiment of this invention. It is a flowchart explaining the main process of the harvesting part of a combine in embodiment of this invention. It is a flowchart explaining the starting process of the harvesting part of a combine in embodiment of this invention. It is a flowchart explaining the stop process of the harvesting part of a combine in embodiment of this invention. It is a flowchart explaining the drive process of the scraping reel of the harvesting part of the combine in embodiment of this invention. It is a flowchart explaining the drive process of the cutting blade of the harvesting part of the combine in embodiment of this invention. It is a flowchart explaining the drive process of the platform auger of the harvesting part of a combine in embodiment of this invention. It is a flowchart explaining the drive process of the feeder house of the harvesting part of a combine in embodiment of this invention.

Explanation of symbols

A General purpose combine,
2 Cutting part,
5 Threshing part,
6 sorting section,
11 Reel electric motor,
12 Cutting blade,
13 Transverse auger (platform auger),
14 Feeder house conveyor.

Claims (4)

In a combine equipped with a traveling section for traveling the machine and a harvesting section for harvesting cereal while traveling by the traveling section,
The combine which provided the feeder house conveyor which conveys a cutting grain cereal in the said cutting part, and provided the electric motor for a drive in the feeder house conveyor.   2. The vehicle speed of the apparatus according to claim 1, further comprising load detection means for detecting a load of the electric motor generated during conveyance, and controlling the vehicle speed of the machine according to the load detected by the load detection means. Combine.   The combine according to claim 1 or 2, wherein the feeder house conveyor stops conveyance when the conveyance amount exceeds a predetermined reference amount.   The combine according to any one of claims 1 to 3, wherein the feeder house conveyor can be stopped in an emergency.

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