JP2010166866A - Clutch operation device of combine harvester - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a combine harvester having a clutch for a reaping system and a clutch for carrying out grains, which can quickly control the engagement or disengagement of each clutch in a state little in misoperations. <P>SOLUTION: The combine harvester is characterized by having a control means 101 for inhibiting the engagement of a clutch 50 for carrying out grains in a state that a reaping clutch 30 is engaged, or for switching the clutch 50 for carrying out the grains into a disengaged state, when the reaping clutch 30 is engaged in a state that the clutch 50 for carrying out the grains is engaged. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  INDUSTRIAL APPLICABILITY The present invention is used for turning on and off the drive clutch of each of the devices in a combine equipped with a cutting and conveying unit, a threshing device, a grain storage device, and the like on a traveling machine body equipped with a traveling device. The present invention relates to an improvement of a combine clutch operating device.

As the above-described combine clutch operating device, those having the structures shown in [1] and [2] below are known.
[1] Regardless of the operation of the reaping clutch or the threshing clutch, the driving clutch of the screw conveyor for carrying out the grain for taking out the grain in the grain tank to the outside can be operated independently (patented) Reference 1).
[2] A configuration in which a cam mechanism is driven by an electric motor to operate a reaping clutch, a threshing clutch, and a feed chain clutch (see Patent Document 2).

JP 2004-89049 A (paragraphs [0034], [0039], FIGS. 4 and 5) JP 2004-105021 A (paragraphs [0041], [0042], [0045], [0046] FIG. 3, FIG. 7, FIG. 11)

As shown in Patent Document 1, in addition to the operation of the harvesting clutch and the threshing clutch, the drive clutch of the screw conveyor for carrying out the grain can be independently turned on and off. Although it is useful in terms of obtaining, there is a possibility that the driving clutch of the screw conveyor for carrying out the grain may be erroneously operated during the work of cutting and threshing.
In addition, as described in Patent Document 2, a cam mechanism driven by an electric motor is used to sequentially operate a reaping clutch, a threshing clutch, and a feed chain clutch. Each clutch can be operated with few erroneous operations according to the order set by the cam mechanism. However, when the configuration is such that only the drive clutch of the grain carrying screw conveyor, which is not described in Patent Document 2, is operated with a separate operating tool, the structure described in Patent Document 1 is provided. Similarly, there is a possibility of erroneous operation of the drive clutch of the grain carrying screw conveyor.

  In order to avoid such an erroneous operation, when any clutch is engaged and operated, the other clutch is not engaged and activated, but once the activated clutch is disengaged, the other clutch is engaged. It is conceivable to configure so that it can be performed. However, in a combine in which various types of clutches are present, operating the clutch that is being driven first in the disengaged state and then operating the clutch that is to be operated next in the engaged state increases the number of target clutches. If the clutch is capable of operating each clutch independently, there is a possibility that the operation order may be wrong even if the operation target is not mistaken. There is a new problem that it is difficult to perform quick clutch switching operation, for example, an unnecessary operation for turning on and off other necessary clutches occurs.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a combine clutch operating device that can perform on / off control of each clutch in a combine equipped with a reaping clutch and a grain carry-out clutch with few erroneous operations and quickly.

[Solution 1]
The technical means of the present invention devised to solve the above-mentioned problems is that the clutch operation of the combine that operates the cutting clutch for turning on and off the driving of the cutting and conveying device and the grain unloading clutch for turning on and off the driving of the grain storage device. In the apparatus, when the harvesting clutch is in the engaged state, the grain carrying-out clutch is prevented from being engaged, and when the harvesting clutch is operated in the engaged state with the grain carrying-out clutch engaged, the grain Control means for switching the grain carry-out clutch to the disengaged state is provided.

[Action and effect]
As described above, the clutch operating device of the combine according to the present invention according to the solution 1 is configured so as to prevent the grain carrying-out clutch from entering when the harvesting clutch is in the engaged state. Even if the grain carrying-out clutch is erroneously operated during operation, the entering operation can be suppressed. In addition, when it is desired to engage and operate the grain carrying-out clutch, it is necessary to perform the necessary cutting operation of the harvesting clutch before the closing operation, so that the forgetting to disconnect the harvesting clutch does not occur.
Then, when the reaping clutch is turned on, the on-going grain carrying out clutch is automatically switched to the off state, so that it is possible to prevent forgetting to turn off the grain carrying out clutch, and such a grain carrying out clutch. The clutch can be switched quickly without requiring a complicated operation such as the operation of engaging the mowing clutch after performing the cutting operation.

Therefore, when performing on / off control of each clutch in a combine including a clutch for harvesting and a clutch for carrying out grain, there is an advantage that it is possible to eliminate a problem that the grain is erroneously discharged during the harvesting operation. Further, there is an advantage that it is possible to reliably avoid forgetting to cut the harvesting clutch when starting to carry out the grain.
If you want to start the harvesting operation immediately after the grain unloading operation or during the discharge operation, you can automatically start the grain unloading by simply turning on the cutting clutch. Therefore, there is an advantage that a quick switching operation can be performed without an erroneous operation.

Overall side view of self-removing combine Overall plan view of self-decomposing combine Plan view showing the arrangement relationship on the fuselage frame Side view showing mowing clutch Schematic diagram showing the transmission system Plan view showing the clutch operating device Side view showing the clutch operating device Development view showing clutch operating device Diagram showing the operation mode of the clutch operating device Time chart showing the mode of operation of the clutch operating device Explanatory drawing which shows the operation form of a clutch operation device Block diagram showing control configuration Main flowchart of control system of clutch operating device Clutch control routine flowchart Top view of instrument panel

Hereinafter, an example of an embodiment of the present invention will be described based on the drawings.
[Overall structure of the combine]
FIG. 1 shows the entire side surface of the self-decomposing combine to which the present invention is applied, and FIG. 2 shows the entire plane.
This combine is provided with a machine body frame 1 formed in a frame shape by a square pipe material or the like, and a pair of left and right crawler type traveling devices 2 are provided at the lower part of the machine body frame 1. A cutting and conveying device 3 connected to the front and left front portions of the body frame 1 so as to be able to move up and down is provided, a threshing device 4 is mounted on the left rear portion of the body frame 1, and a grain storage device is mounted on the right rear portion of the body frame 1. 5, and further includes a driving unit 6 provided on the right front portion of the body frame 1, a boarding operation unit 20 formed on the upper side of the driving unit 6, and the like.

  As shown in FIG. 4, the front portion of the machine body frame 1 supports the horizontal cylinder portion on the rear end side of the cutting main frame 3 </ b> A of the cutting and conveying device 3, and is oriented forward and backward around the horizontal axis x <b> 1. A cutting frame support base 17 is provided for supporting the vertical cylinder portion of the vertical cylinder portion so as to be swingable up and down. The mowing main frame 3A is provided with a power transmission shaft (not shown) for transmitting power to the pulling device 31 and the mowing device 32 of the mowing transport device 3.

[Configuration of Airframe Frame]
As shown in FIG. 3, the body frame 1 is in a state where it intersects with a pair of left and right main frames 10, 10 in the shape of a square pipe that is long in the front-rear direction and in a direction crossing the main frames 10, 10 in the left-right direction. It is formed in a lattice frame shape with a large number of lateral frames 11 mounted and installed, and front and rear side frames 12 mounted and installed on the outer end side of the machine body of the horizontal frame 11. Although not shown, a machine frame plate 13 made of a triangular plate-shaped metal plate material having a substantially chevron-shaped cross section is provided between the right side of the main frames 10 and 10 and the side frame 12. .
The main frames 10, 10, the lateral frame 11, the side frame 12, and the machine frame plate 13 are integrated to form a machine frame constituent material.

As shown in FIG. 3, the threshing device 4 is mounted on the left rear portion and the grain storage device 5 is mounted on the right rear portion on the body frame 1 in a state of being distributed to both sides of the left and right main frames 10 and 10. The driving part 6 is provided in the right front part.
Although the said machine frame plate 13 is provided in the state which overlaps with the downward side of the said grain storage apparatus 5 by planar view, in this overlapping part, the bottom face of the said grain storage apparatus 5 is a horizontal direction center. It is formed in the slope which becomes low as the screw conveyor 55 side of a part location. For this reason, there is actually a vertical gap between the bottom side of the grain storage device 5 and the machine frame plate 13. On the upper surface side of the machine frame plate 13, a groove-shaped portion that is open upward is formed by a triangular wave-shaped valley of the machine frame plate 13. When the grain storage device 5 swings and opens outward around the vertical axis y, the upper surface side of the machine frame plate 13 is in a state in which an operator can board for maintenance work or the like. Opened.

A grain carrying out auger 52 of the grain storage device 5 is disposed at the right rear end of the machine frame 1 on the rear side of the machine frame plate 13. Is provided with a fuel tank 16.
On the machine body frame 1 on the front side of the machine frame plate 13, there is provided a prime mover 6 on which an engine 60, a hydraulic pump 65, and a radiator 61 are mounted on the right side, and further on the front side of the prime mover 6. A battery 69 serving as a power supply device is mounted on the body frame 1 extended in FIG.
Further, a transmission case 26 having a drive axle (not shown) for transmitting driving force to the left and right crawler type traveling devices 2 is provided between the main frames 10 and 10 of the body frame 1. The mission case 26 also serves as a tank for storing lubricating oil for lubricating and cooling gears in the mission case 26.
Further, a hydraulic oil tank 27 for supplying hydraulic oil to various hydraulic devices is mounted on the aircraft frame 1 closer to the left side of the aircraft than the transmission case 26.

  Various working clutches are turned on and off using the power of a common electric motor 70 on the body frame 1 at a position on the right side of the main frames 10 and 10 and on the right side of the place where the threshing device 4 is present. A clutch operating device A for control is provided. The location of the clutch operating device A can be operated by looking into the right lateral side of the machine body when the grain storage device 5 is swung around the rear longitudinal axis y to be in an open posture. This is a possible position.

[Composition of the motor section]
As shown in FIGS. 3 and 5, the prime mover 6 includes an engine 60 mounted on the fuselage frame 1, a hydraulic pump 65 attached to the side of the engine 60, a radiator 61 for cooling the engine, and an oil cooler. 66 and a blower fan 62 capable of blowing air by switching the blowing direction with respect to the radiator 61 between forward and reverse. As shown in FIG. 1, an opening 63 for introducing outside air with a dust-proof net is provided on the right outer side of the machine body at the location facing the blower fan 62, for suppressing the inhalation of dust from the outside. .

From the engine muffler 67 connected to the engine 60, an exhaust pipe 68 that guides engine exhaust toward the rear of the body is extended to the lower side of the body frame 1.
Although not shown in detail, the blower fan 62 includes an operation body 64 that can be slid on the right engine output shaft 60a, and the blade angle of the blower fan 62 is changed by sliding the operation body 64. This is a well-known device that is configured to be freely switchable between a forward direction and a reverse direction.

  Although not shown, the boarding operation unit 20 is provided with a backflow operation tool (not shown) for the operation body 64 of the blower fan 62. The operation body 64 is operated only while the backflow operation tool is being operated. And it is comprised so that a ventilation direction can be reversed.

[Composition of auger for grain export]
As shown in FIGS. 1, 2, and 3, the grain carrying out auger 52 provided at the right rear end portion of the machine frame 1 on the rear side of the machine frame plate 13 is fixed to the machine frame 1 side. A drive motor 5M which is an example of an actuator is provided, and this drive motor 5M allows the vertical cylinder portion 52A to turn around a vertical axis y which is the center of swinging of the grain storage device 5 and to store the grain. The device 5 is configured to be rotatable relative to the grain tank 51.
Further, the horizontal cylinder portion 52B connected to the upper end side of the vertical cylinder portion 52A is configured to be swingable up and down around the horizontal axis x, and the vertical movement is performed by the vertical cylinder portion 52A and the horizontal cylinder portion. This is performed by a hydraulically driven expansion / contraction cylinder 5S as a hydraulic actuator provided between 52B and 52B.

[Configuration of boarding operation section]
As shown in FIG. 2, the boarding operation unit 20 includes a shift lever 21 that performs a forward / reverse shift operation of the airframe and a steering operation lever 22 that performs a steering operation of the airframe. And an operation panel 23 for instructing the operation order.

  This operation panel 23 is equipped with a pillow handling threshing start button B1, a low-speed reaping / threshing start button B2, a high-speed reaping / threshing start button B3, a grain carry-out button B4, and a work start / end button B5. Each of these buttons B1, B2, B3, B4, and B5 is configured to be in an on state by a push-in operation and to return to an original cut-out state by a second push operation. Then, an operation signal which is a command by human operation is input to the control device 100 which will be described later, the operation of the clutch operation device A is controlled by the control device 100, and the presence / absence of driving of various working devices and the driving start order are controlled. To do.

  When the work start / end button B5 is pushed in a state where none of the work devices to be controlled by the control device 100 is driven, only the threshing device 4 starts to be driven and the other work devices are stopped. Let the state be Then, after any of the buttons B1, B2, B3, B4 other than the work start / end button B5 is entered and operated, when the work start / end button B5 is pushed, Functions to stop the device.

When the pillow handling threshing start button B1 is operated, the threshing device 4 and the feed chain 42 are driven, and the other working devices are in a stopped state, and the hand-held threshing operation in a state where the machine body is stopped is possible. It becomes a state. When the low-speed mowing and threshing start button B2 is operated, the mowing and conveying device 3 is driven in addition to the threshing device 4 and the feed chain 42 described above.
When the high-speed mowing and threshing start button B3 is operated, the mowing transmission mechanism 35 is switched to the high speed side, and the above mowing and threshing work can be performed at a high speed.
Further, the grain carry-out button B4 is in a work state in which only the grain storage device 5 is driven and the grain is discharged in a state where all the operations of the above-described harvesting work related devices are stopped.
The control mode will be described later together with the configuration of the control system.

[Configuration of transmission system]
As shown in FIG. 3, the engine 60 is mounted on the body frame 1 in such a posture that the axial center direction of the output shaft 60 a is in the left-right direction. As shown in FIG. 5, the transmission from the engine 60 to the left and right crawler type traveling devices 2 is performed from the left end portion of the output shaft 60a of the engine 60 projecting toward the left and right central portion of the machine body. This is performed via a transmission system for traveling over the drive wheels 2A of the traveling device 2. The traveling transmission system includes a belt-type transmission 24, a hydrostatic continuously variable transmission 25 provided as a main transmission, and a gear-type transmission (not shown) incorporated in the transmission case 26 as an auxiliary transmission. , Etc.

  Each of the left and right crawler type traveling devices 2 swings the shift lever 21 provided in the boarding operation unit 20 in the front-rear direction, thereby switching between the stepless speed change operation and the forward / backward movement by the hydrostatic continuously variable transmission 25 In addition, the steering operation lever 22 provided in the boarding operation unit 20 is swung in the left-right direction, so that the gear-type transmission in the mission case 26 moves straight, and the left and right turns slowly. It is configured to be able to switch between the state and the sudden turn state on the left and right.

  The chopping and conveying device 3 is configured such that the power after the shift by the hydrostatic continuously variable transmission 25 is transmitted via the one-way clutch 25a, the belt tension type reaping clutch 30, and the like, so The reaping device 32, the culm transporting device 33, and the like are driven, and with the traveling of the machine body, the plurality of weeding tools 34 mounted on the front end weed the planted cereal culm, and each pulling device 31 Causes the planted culm after weeding, the cutting device 32 cuts the planted side of the planted culm, and the grain transporting device 33 turns the trimmed cereal from the upright position to the rear and switches backward. The chopping and conveying device 3 can be moved up and down by operating the lift cylinder 18 by swinging the steering lever 22 in the front-rear direction. ing

The power transmission structure to the cutting and conveying apparatus 3 is configured as follows.
As shown in FIGS. 4 and 5, the power after shifting by the hydrostatic continuously variable transmission 25 is output from a cutting output pulley 36a provided on the upper lateral side of the mission case 26, as shown in FIG. The cutting output pulley 36a, the cutting input pulley 36b supported by the cutting main frame 3A, the transmission belt 37 wound between the cutting output pulley 36a and the cutting input pulley 36b, and the tension It is transmitted to a power transmission shaft (not shown) in the cutting main frame 3A via a cutting clutch 30 constituted by the wheel 38.

  A tension arm 39 for pressing and urging the tension wheel 38 of the reaping clutch 30 toward the transmission belt 37 is a horizontal shaft 17a whose intermediate portion in the length direction is a swing fulcrum with respect to the reaping frame support base 17. A tension ring 38 that is pivotally supported around the transmission belt and moves in a distance with respect to the transmission belt 37 is attached to one end side, and an operation wire 30a is connected to the other end side. Therefore, when the operation wire 30a is pulled by the cam mechanism 8 of the clutch operating device A described later, the tension wheel 38 is pressed against the outer peripheral surface of the transmission belt 37 from the lower side, and the clutch is engaged. When the operation wire 30a is loosened, the tension wheel 38 shifts to the lower side away from the outer peripheral surface of the transmission belt 37 and the clutch is disengaged.

When it is desired to change the cutting speed in the cutting and conveying apparatus 3 not only in accordance with the stepless speed change by the hydrostatic continuously variable transmission 25 but also in accordance with the conditions of the field and the state of lying of the stems and the like. The gear case 26 is constructed so that it can be operated by a two-step shift operation by a cutting and shifting mechanism 35 constituted by a dedicated gear transmission mechanism installed in the mission case 26.
In the two-step shift operation by the cutting and shifting mechanism 35, a known shift operating tool (not shown) is linked to a clutch operating device A described later via an operating wire 35a. By this operation, the cutting operation at high speed and the cutting operation at low speed can be selected.

The threshing device 4 is the power of the engine 60 transmitted through the belt-tension type threshing clutch 40, and the barrel 41 and the like are driven. It is constituted by a known structure that handles and processes the head side and supplies the grain obtained by the sorting process to the grain tank 51 of the grain storage device 5 via the first recovery screw (not shown). ing.
The belt tension type threshing clutch 40 is composed of a transmission belt 43 stretched between an output pulley 60 b on the engine side and an input pulley 42 of the threshing device 4, and a tension pulley 44. An operation wire 40a for pulling the tension pulley 44 to switch to a clutch engaged state is linked to a clutch operating device A described later.

  The feed chain 47 is configured such that power from the engine 60 is transmitted by a transmission system branched from the transmission system to the threshing device 4 by a transmission belt 48 and via a tension clutch type feed chain clutch 49. It is. Then, by operating the feed chain clutch 49, the threshing device 4 can be driven with the timing shifted from the start or end of driving.

  The grain storage device 5 includes a Glen tank 51 and a grain carrying out auger 52, and is configured such that the power of the engine 60 is transmitted to the grain carrying out auger 52. That is, the transmission belt 54 is stretched over the input portion 53 of the grain storage device 5 from the portion of the output shaft 60a of the engine 60 that protrudes from the right lateral side toward the outer side of the machine body. A belt tension type grain carry-out clutch 50 for turning on and off the power transmission is provided.

The Glen tank 51 has a working position where the whole is located behind the engine 60 around the longitudinal axis y provided at the rear part thereof, and a front part of the Glen tank 51 protrudes outward to the right of the fuselage frame 1 so that the rear side of the engine 60 It is configured to be able to swing and displace over a maintenance position that opens the position, and to be able to hold the position at the work position and the maintenance position by a lock mechanism (not shown).
The screw conveyor 55 and the input part 53 for the grain carrying out auger 52 provided at the bottom of the Glen tank 51 that swings and displaces in this way allow the Glen tank 51 to swing around the longitudinal axis y. It has a disengagement structure.

That is, as shown in FIG. 5, an input pulley 56 on which a transmission belt 54 is stretched, and a transmission shaft 57 that is spline-fitted so as to be integrally rotatable with the input pulley 56 and to be relatively slidable are provided in the machine body. It is supported by a bearing bracket 10b provided on the frame 1 side.
The power transmitted to the transmission shaft 57 is transmitted to an input transmission shaft 58 that is engaged and disengaged with respect to the transmission shaft 57, and the bevel gear 58 a of the input transmission shaft 58 and the screw conveyor 55 The screw conveyor 55 and the grain carrying out auger 52 are transmitted via a bevel gear 55a provided on the shaft end side.
The input transmission shaft 58 is supported on the Glen tank 51 side, and includes a recessed engagement portion 58b that can be inserted into and removed from the transmission shaft 57, while the rotational power from the transmission shaft 57 is transmitted. Since it can be inserted and removed in the axial direction, engagement and disengagement associated with the swing of the Glen tank 51 around the longitudinal axis y can be allowed.
Reference numeral 59 in the drawing denotes a pressing spring for pressing and urging the transmission shaft 57 toward the input transmission shaft 58.

[Configuration of clutch operating device]
As shown in FIGS. 6 to 11, in the present invention, a cam-driven clutch operating device A is employed as a combine clutch operating device for turning on and off the clutches included in the above various working devices. The clutch operating device A includes a driving device 7 that generates a driving force and a cam mechanism 8 that is driven by the driving device 7.

The drive device 7 is an electric motor 70 as a power source, a gear mechanism 72 that transmits the power of the electric motor 70 to the cam mechanism 8, and a detection mechanism that detects the operating state of the cam mechanism 8 driven by the electric motor 70. The potentiometer 73 and a motor control circuit provided as a control program in the control device 100 composed of a microcomputer, which will be described later, as means for controlling the operation of the electric motor 70.
When the operation signals of the various operation buttons B1 to B5 provided on the control panel 20C are input to the control device 100, the electric motor 70 outputs a control command based on the operation signals from the control device 100. 70 is driven in the forward direction or the reverse direction. The driving force of the electric motor 70 is output as the rotational power of the output gear 74 attached to the motor output shaft 71. The gear mechanism 72 is configured by the output gear 74 and a gear portion 75 formed on a part of the outer periphery of the cam plate of the cam mechanism 8 described later.
The driving state of the cam mechanism 8 by the output gear 74 is detected by a potentiometer 73 provided at the shaft end of the cam shaft 80, and a feedback signal based on the detection result is transmitted to the control device 100.

The cam mechanism 8 is a cam plate group composed of a combination of a first cam plate 81, a second cam plate 82, and a third cam plate 83 mounted so as to rotate integrally with a common cam shaft 80. And a cam follower group in contact with each of the cam plates 81, 82, 83.
Among the cam follower group, the first cam plate 81 includes a Glen tank cam follower 84 that operates the grain carry-out clutch 50 that is guided in contact with the camshaft 80 on the front side of the machine body, and a camshaft 80. There is also provided a threshing cam follower 85 for operating the threshing clutch 40 that is guided by contact on the rear side of the machine body.
The feed cam follower 86 that operates the feed chain clutch 49 that is guided in contact with the second cam plate 82 on the front side of the machine body with respect to the camshaft 80, and the rear side of the machine body with respect to the camshaft 80. And a reaping cam follower 87 for operating the reaping clutch 30 guided.
For the third cam plate 83, there is no cam follower on the front side of the body relative to the camshaft 80, and the shift operating means of the cutting transmission mechanism 35 that is guided in contact with the rear side of the body relative to the camshaft 80 is operated. A mowing transmission system cam follower 88 is provided. A gear portion 75 that constitutes the gear mechanism 72 together with the output gear 74 of the electric motor 70 is formed on a part of the outer peripheral edge of the third cam plate 83.

  The cam followers 84 and 86 existing on the front side of the machine body from the camshaft 80 are respectively arranged in the longitudinal direction of the swinging pieces 84a and 86a bent in a U-shaped section with respect to the clutch case 76. A pivot shaft 77 is mounted so as to be able to be inserted and removed from the right lateral outer side. Further, rollers 84b and 86b are provided on the upper end sides in the longitudinal direction of the swinging pieces 84a and 86a so as to come into contact with the outer peripheral edges of the cam plates 81 and 82 while entering the bent U-shaped portion. It is. Operation wires 50a and 44a for turning on and off the grain carrying-out clutch 50 and the feed chain clutch 49 are connected to the lower ends in the longitudinal direction of the swing pieces 84a and 86a, respectively.

The cam followers 85, 87, 88 existing on the rear side of the machine body with respect to the camshaft 80 have lower end portions in the longitudinal direction of the swinging pieces 85 a, 87 a, 88 a formed to be bent in a U-shaped section, respectively. On the other hand, a pivot shaft 78 is mounted so as to be able to be inserted and removed from the right lateral outer side of the machine body.
A roller 85b that contacts the outer peripheral side of the cam plates 81, 82, and 83 in the bent U-shaped portion at the intermediate portion in the longitudinal direction of the swinging pieces 85a, 87a, and 88a. , 87b, 88b are provided. And on the upper end side in the longitudinal direction of each swing piece 85a, 87a, 88a, respectively, the operation wire 40a for operating the threshing clutch 40, the operation wire 30a for operating the cutting clutch 30, and the cutting An operation wire 35a for operating the speed change operation means of the speed change mechanism 35 is connected.

The first cam plate 81 has, on its outer periphery, a glen tank system cam surface 81a for operating the glen tank system cam follower 84 and a threshing system cam surface 81b for operating the threshing system cam follower 85. It is formed at a location substantially opposed across the shaft 80.
The second cam plate 82 has a feed system cam surface 82a for operating the feed system cam follower 86 and a cutting system cam surface 82b for operating the cutting system cam follower 87 on the outer peripheral edge thereof. It is formed in the place which opposes on both sides.
The third cam plate 83 is provided with a cutting transmission system cam surface 83a for operating the cutting transmission system cam follower 88 at the outer peripheral edge thereof, and the third cam plate 83 and the first cam plate 81 are provided. A gear portion 75 for transmitting a driving force to the second cam plate 82 is formed.

[Operation by clutch operating device]
Next, the operation mode by the clutch operating device A will be described with reference to FIGS.
9 shows the cam surfaces 81a, 81b, 82a of the cam plates 81, 82, 83 within the rotation angle range of the cam shaft 80 set by the attachment range of the gear portion 75 formed on the third cam plate 83. FIG. , 82b, 83a and the cam followers 84, 85, 86, 87, 88, the range in which the function appears is represented by an angle distribution diagram within the rotation angle range.
FIG. 10 is a time chart with the vertical axis representing the type of work device and the horizontal axis representing operation timing. FIG. 11 is a graph illustrating the associated operation state between each cam plate and the cam follower, with the horizontal axis indicating the type of work device and the vertical axis indicating the time axis.

  The position of the symbol N shown in FIG. 9 indicates a neutral position in which all the clutches and the like operated by the clutch operating device A are not operated to the operating side, and no work device is driven. Yes. A similar neutral position N is indicated by the same reference numeral N in FIGS.

In FIG. 9, symbol a indicates that the first cam plate 81 is rotated counterclockwise from the neutral position N, and the grain tank system cam surface 81 a operates the grain tank system cam follower 84 to move the grain carry-out clutch 50. This indicates the position where the mark is entered and corresponds to the position indicated by the same symbol a in FIG. Further, in FIG. 11, the first cam plate 81 and the Glen tank system cam follower 84 are shown in contact with each other at the level “a” shown at the top.
At this time, the positions of the second cam plate 82 and the third cam plate 83 are not directly shown in FIG. 9, but FIG. 10 shows the operations of the threshing clutch 40 and the grain carrying-out clutch 50. It can be seen that the line relates to the first cam plate 81, and the line indicating the operation of the cutting transmission mechanism 35 relates to the third cam plate 83.
Therefore, also in FIG. 10, at the position a, only the grain carrying-out clutch 50 is “ON”, all the other clutches are “OFF”, and the cutting transmission mechanism 35 is in the low speed state. is there.
In FIG. 11, the second cam follower 86 is in contact with the feed system cam surface 82 a of the second cam plate 82 at the stage indicated by symbol “a”, but the feed chain clutch 49 is originally biased to the entry side. Therefore, the feed system cam surface 82a operates the second cam follower 86 to the cut side to keep the feed chain clutch 49 in the cut state.

In FIG. 9, the symbol b indicates that the first cam plate 81 is rotated clockwise from the neutral position N, and the grain tank system cam surface 81 a moves to a position away from the grain tank system cam follower 84 to carry out the grain delivery. The threshing system cam surface 81b operates the threshing system cam follower 85 and the threshing clutch 40 is engaged.
In FIG. 10 as well, the position indicated by the same symbol b corresponds to the same state. Moreover, in FIG. 11, it has shown by the contact state of the 1st cam board 81 and the threshing system cam follower 85 in the step of the code | symbol b illustrated in the 3rd step from the top.
At this time, as shown in FIGS. 10 and 11, the second cam plate 82 maintains both the feed chain clutch 49 and the cutting clutch 30 in the clutch disengaged state.
Further, as shown in FIGS. 10 and 11, the third cam plate 83 maintains the low speed state of the cutting transmission mechanism 35.

9, the first cam plate 81 is rotated clockwise from the neutral position N, and the threshing cam surface 81b operates the threshing cam follower 85 so that the threshing clutch 40 is engaged. Continue to maintain.
At this time, in the second cam plate 82 that rotates clockwise, the feed cam surface 82a releases the cutting operation state of the feed cam follower 86, and the feed chain clutch 49 is switched to the clutch engaged state. .
At this time, the cutting system cam surface 82 b of the second cam plate 82 has not reached the state in which the cutting system cam follower 87 acts, and the cutting system cam follower 87 maintains the cutting state of the cutting clutch 30.
Also in FIG. 10, the position indicated by the same symbol c is in the same state, that is, the threshing clutch 40 and the feed chain clutch 49 are in the engaged state, and the cutting clutch 30 is in the disengaged state.
FIG. 11 shows a state in which the threshing clutch 40 is kept in contact with the first cam plate 81 and the threshing system cam follower 85 at the stage indicated by the symbol c. Along with this, the feed cam surface 82a of the second cam plate 82 releases the cutting operation of the feed cam follower 86, and the feed chain clutch 49 is switched to the clutch engaged state. The cutting cam surface 82b of the second cam plate 82 has not reached the state in which the cutting cam follower 87 acts, and the cutting cam follower 87 maintains the cutting clutch 30 in the disconnected state.
Further, as shown in FIGS. 10 and 11, the third cam plate 83 maintains the low speed state of the cutting transmission mechanism 35.

9, the first cam plate 81 is rotated clockwise from the neutral position N, and the threshing cam surface 81b operates the threshing cam follower 85 so that the threshing clutch 40 is engaged. Continue to maintain.
The feed cam surface 82a of the second cam plate 82 that rotates clockwise is in a state in which the cutting operation of the feed cam follower 86 has been released, and maintains the state in which the feed chain clutch 49 is switched to engage the clutch. .
At this time, the cutting system cam surface 82b of the second cam plate 82 operates the cutting system cam follower 87 to switch the cutting clutch 30 to the clutch-engaged state.
Also in FIG. 10, the position indicated by the same symbol d is in the same state, that is, in addition to the threshing clutch 40, the feed chain clutch 49 and the reaping clutch 30 are both switched to the clutch engaged state. Yes.
FIG. 11 shows a state in which the threshing clutch 40 is kept in contact with the first cam plate 81 and the threshing cam follower 85 at the stage indicated by the symbol d. At the same time, the cutting cam surface 82 b of the second cam plate 82 operates the cutting cam follower 87, and at the same time, the feed cam surface 82 a cancels the cutting operation of the feed cam follower 86, and the feed chain clutch 49 and the cutting clutch 30. Are both switched to the clutch engaged state.
Further, as shown in FIGS. 10 and 11, the third cam plate 83 maintains the low speed state of the cutting transmission mechanism 35.

9, the first cam plate 81 is rotated clockwise from the neutral position N, the threshing cam surface 81b operates the threshing cam follower 85, and the threshing clutch 40 is engaged. Continue to maintain.
The cutting cam surface 82b of the second cam plate 82 that continues to rotate clockwise operates the cutting cam follower 87. At the same time, the feed cam surface 82a cancels the cutting operation of the feed cam follower 86. The clutch 49 and the reaping clutch 30 are both switched to the clutch engaged state.
At this time, the cutting transmission system cam surface 83a of the third cam plate 83 operates the cutting transmission system cam follower 88 to operate the operation shifter of the cutting transmission mechanism 35 to the high speed side.
Also in FIG. 10, the position indicated by the same symbol e is in the same state, that is, the feed chain clutch 49 and the cutting clutch 30 are both engaged, and the cutting transmission mechanism 35 is operated to the high speed side. Is shown.
FIG. 11 shows a state in which the threshing clutch 40 is kept in contact with the first cam plate 81 and the threshing cam follower 85 at the stage indicated by symbol e. At the same time, the cutting cam surface 82 b of the second cam plate 82 operates the cutting cam follower 87, and at the same time, the feed cam surface 82 a cancels the cutting operation of the feed cam follower 86, and the feed chain clutch 49 and the cutting clutch 30. , Both of which are switched to the clutch-engaged state. The cutting high-speed cam surface (not shown) of the third cam plate 83 operates the cutting gear shifting cam follower (not shown). The operating shifter of the cutting transmission mechanism 35 is operated to the high speed side.

[Control system configuration]
As shown in FIG. 12, the operation of the electric motor 70 that is the power source of the cam mechanism 8 that operates the cutting clutch 30, the threshing clutch 40, the feed chain clutch 49, the grain carrying-out clutch 50, and the cutting transmission mechanism 35 is performed. A control device 100 including a microcomputer that inputs a motor control circuit 101 to be controlled as a control program is configured as follows.

Each of a pillow handling threshing start button B1, a low-speed cutting / threshing start button B2, a high-speed cutting / threshing button B3, a grain carry-out button B4, and a work start / end button B5 provided on the operation panel 23 of the boarding operation unit 20 is an operation switch. It is comprised so that the operation signal may be input into the control apparatus 100.
In the control device 100, the control circuit controls the electric power of the clutch operating device A based on the determination of which of the buttons B 1, B 2, B 3, B 4, B 5 is operated and based on the detection result of the potentiometer 73. A control command is output to the motor 70 as follows.

When it is detected that the pillow handling threshing start button B1 has been operated, the detection position of the camshaft 80 detected by the potentiometer 73 is the position indicated by the symbol c in FIG. 9 (referred to as a pillow handling threshing start position c). If the position is not further away from the neutral position than clockwise, the electric motor 70 drives the gear mechanism 72 to rotate the cam shaft 80 of the cam mechanism 8 clockwise. When the potentiometer 73 detects that the pillow handling threshing start position c has been reached, a stop command is output to the electric motor 70.
When the detection position of the camshaft 80 detected by the potentiometer 73 is a position that is further away from the neutral position in the clockwise direction than the pillow handling threshing start position c, the electric motor 70 rotates in the reverse direction and the gear mechanism 72 is rotated. Driven to rotate the cam shaft 80 of the cam mechanism 8 counterclockwise. When the potentiometer 73 detects that the pillow handling threshing start position c has been reached, a stop command is output to the electric motor 70. In addition, when the detection position of the camshaft 80 detected by the potentiometer 73 is the pillow handling threshing start position c, a drive command for the electric motor 70 is not output.
In this state, the threshing cam surface 81b of the first cam plate 81 operates the threshing cam follower 85, and the threshing clutch 40 is engaged and operated. Thereafter, when it is detected that the work start / end button B5 is operated, the electric motor 70 is driven to rotate the camshaft 80 counterclockwise, and when it is detected that the neutral position N has been reached, Command to stop at.

When it is detected that the low-speed mowing and threshing start button B2 has been operated, the detection position of the camshaft 80 detected by the potentiometer 73 is a position indicated by a symbol d in FIG. 9 (referred to as a low-speed mowing and threshing start position d for convenience). If the position is not further away from the neutral position than clockwise, the electric motor 70 drives the gear mechanism 72 to rotate the cam shaft 80 of the cam mechanism 8 clockwise. When the potentiometer 73 detects that the low-speed mowing and threshing start position d has been reached, a stop command is output to the electric motor 70.
When the detection position of the camshaft 80 detected by the potentiometer 73 is a low-speed mowing and threshing start position d or a position farther from the neutral position than the low-speed mowing and threshing start position d, the electric motor 70 The drive command for is not output.
In this state, the threshing system cam surface 81b of the first cam plate 81 operates the threshing system cam follower 85 so that the threshing clutch 40 is engaged and operated, and the reaping system cam of the second cam plate 82 is maintained. The surface 82b operates the cutting system cam follower 87, and at the same time, the feed system cam surface 82a cancels the cutting operation of the feed system cam follower 86, and the feed chain clutch 49 and the cutting clutch 30 are both switched to the clutched state. is doing.
Thereafter, when it is detected that the work start / end button B5 is operated, the electric motor 70 is driven to rotate the camshaft 80 counterclockwise, and when it is detected that the neutral position N has been reached, Command to stop at.

When it is detected that the high-speed mowing and threshing start button B3 has been operated, the detection position of the camshaft 80 detected by the potentiometer 73 is from the position of symbol e in FIG. 9 (referred to as a high-speed mowing and threshing position e for convenience). If the position is not a position away from the neutral position in the clockwise direction, the electric motor 70 drives the gear mechanism 72 and rotates the cam shaft 80 of the cam mechanism 8 in the clockwise direction. When the potentiometer 73 detects that the high-speed mowing and threshing position e has been reached, a stop command is output to the electric motor 70.
In this state, the threshing system cam surface 81b of the first cam plate 81 operates the threshing system cam follower 85 so that the threshing clutch 40 is engaged and operated, and the reaping system cam of the second cam plate 82 is maintained. The surface 82b operates the cutting system cam follower 87, and at the same time, the feed system cam surface 82a cancels the cutting operation of the feed system cam follower 86, and the feed chain clutch 49 and the cutting clutch 30 are both switched to the clutched state. is doing.
Further, the cutting high-speed system cam surface 83a of the third cam plate 83 operates the cutting transmission system cam follower 88 in accordance with the operation to the high-speed cutting / threshing position e, so that the operation shifter of the cutting transmission mechanism 35 is moved to the high speed side. It is operating.
Thereafter, when it is detected that the work start / end button B5 is operated, the electric motor 70 is driven to rotate the camshaft 80 counterclockwise, and when it is detected that the neutral position N has been reached, Command to stop at.

When it is detected that the grain unloading start button B4 has been operated, the detection position of the camshaft 80 detected by the potentiometer 73 is from the position a in FIG. 9 (referred to as the grain unloading position a for convenience). If the position is not counterclockwise and away from the neutral position, the electric motor 70 drives the gear mechanism 72 and rotates the cam shaft 80 of the cam mechanism 8 counterclockwise. When the potentiometer 73 detects that the grain unloading position a has been reached, a stop command is output to the electric motor 70.
When the detection position of the camshaft 80 detected by the potentiometer 73 is the grain unloading position a, the drive command for the electric motor 70 is not output. In this state, the grain tank system cam surface 81a of the first cam plate 81 operates the grain tank system cam follower 84, and the grain carrying-out clutch 50 is engaged.
Thereafter, when it is detected that the work start / end button B5 is operated, the electric motor 70 is driven to rotate the camshaft 80 clockwise, and when it is detected that the neutral position N is reached, at that position. Command to stop.

[Control form of motor control circuit]
The flow of control by the motor control circuit 101 of the clutch operating device A will be described based on the flowcharts of FIGS.
[1] As shown in FIG. 13, in the main routine of the motor control circuit 101, in step # 1 immediately after the start of control, the flag f = 0 is initialized and the next clutch control routine # 2 is started. After exiting the clutch control routine # 2, it is determined whether or not there is a control end condition such as turning off a key switch (not shown). If not, the clutch control routine # 2 is executed again.

In clutch control routine # 2 shown in FIG. 14, control is performed as follows.
[2] First, it is detected that the work start / end button B5 has been turned on (on), and when it is detected, the value of the flag f is determined (steps # 4 and # 5).
[3] When the value of the flag f is f = 0, if the pillow handling threshing start button B1 is not OFF, that is, if the pillow handling threshing start button B1 is ON, the feed chain 47 is driven. And the value of the flag f is set to f = 1 (steps # 6, # 7, # 17). Conversely, if the pillow handling threshing start button B1 is OFF (cut), the operation state of the next low-speed reaping / threshing start button B2 is determined (steps # 6 and # 8).
[4] If the low-speed mowing and threshing start button B2 is not OFF (cut), that is, if the low-speed mowing and threshing start button B2 is ON, the grain-carrying clutch 50 is turned off (cut), and then the cutting clutch 30 is turned on. While turning on (entering), the cutting transmission mechanism 35 is switched to the low speed side. Conversely, if the low-speed mowing and threshing start button B2 is OFF (cut), the operation state of the next high-speed mowing and threshing start button B3 is determined (steps # 8, # 9, # 10, and # 11).
[5] If the high-speed mowing and threshing start button B3 is not OFF (cut), that is, if the high-speed mowing and threshing start button B3 is ON, after the grain carrying-out clutch 50 is turned off (cut), the mowing clutch 30 is turned off. In addition to turning on (turning on), the cutting transmission mechanism 35 is switched to the high speed side, and the value of the flag f is set to f = 1 (steps # 11, # 12, # 13, # 17). On the contrary, if the high-speed cutting / threshing start button B3 is OFF (cut), the operation state of the next grain carry-out button B4 is determined (steps # 11 and # 14).
[6] If the grain carrying out button B4 is not OFF (cut), that is, if the grain carrying out button B4 is ON, the grain carrying out clutch 50 is turned on (entered), and then the flag f is set. The value is set to f = 1 (steps # 15 and # 17).
[7] If the grain carrying-out button B4 is OFF (cut), that is, if any of the buttons B1, B2, B3, B4 is OFF (cut), only the threshing clutch 40 is turned on (entered). ) After the operation, the value of the flag f is set to f = 1 (steps # 16 and # 17).

[8] In step # 5, if the value of the flag f is f = 1, if the pillow handling threshing start button B1 is not OFF (cut), that is, if the pillow handling threshing start button B1 is ON, the feed The chain clutch 49 is turned off (disengaged) to stop driving the feed chain 47, the threshing clutch 40 is turned off (disengaged), and the value of the flag f is set to f = 0 (steps # 18, # 19, # 27). Conversely, if the pillow handling threshing start button B1 is OFF (cut), the operation state of the next low-speed reaping / threshing start button B2 is determined (steps # 18, # 20).
[9] If the low speed mowing and threshing start button B2 is not OFF (cut), that is, if the low speed mowing and threshing start button B2 is ON, the mowing clutch 30 is turned off (cut), and the value of the flag f is set to f = Set to 0 (steps # 20, # 21, and # 27). Conversely, if the low-speed mowing and threshing start button B2 is OFF (cut), the operation state of the next high-speed mowing and threshing start button B3 is determined (steps # 20 and # 22).
[10] If the high-speed mowing and threshing start button B3 is not OFF (cut), that is, if the high-speed mowing and threshing start button B3 is ON, the mowing clutch 30 is turned off (cut), and the mowing transmission mechanism 35 is moved to the low speed side. And the value of the flag f is set to f = 0 (steps # 22, # 23, # 27). On the other hand, if the high-speed mowing and threshing start button B3 is OFF (cut), the operation state of the next grain carry-out button B4 is determined (steps # 22 and # 24).
[11] If the grain carry-out button B4 is not OFF (cut), that is, if the grain carry-out button B4 is ON, the grain carry-out clutch 50 is turned off (cut), and then the flag f is set. The value is set to f = 0 (steps # 24, # 25, # 27).
[12] If the grain delivery button B4 is OFF (cut), that is, if any of the buttons B1, B2, B3, B4 is OFF (cut), only the threshing clutch 40 is turned OFF (cut). ) After the operation, the value of the flag f is set to f = 0 (steps # 24, # 26, # 27).

[Others]
FIG. 15 shows the instrument panel 9 in the boarding operation unit 20.
The instrument panel 9 includes a working speed meter 90 indicating a vehicle speed at the center and a load meter 91, an engine tachometer 92 on the left side, and a fuel gauge 93 on the right side.

  In the working speed meter 90, the vehicle speed detected by the vehicle speed sensor 95 is displayed in an analog manner by a pointer 90a, and the load meter 91 is constituted by a large number of LEDs 94 arranged in an arc shape near the outer peripheral edge thereof. The LED 94 emits green light in the light load range 94a shown in the drawing, yellow light in the medium load range 94b larger than the light load, red light in the larger heavy load range 94c, and the density of each color. The LED 94 of the corresponding color is provided so as to become darker as the load increases.

  As shown in FIG. 12, the load meter 91 is supplied from an accelerator set position detector 96 that detects the operation position of the accelerator pedal 28 whose depression position is set so that a predetermined engine speed can be obtained in a no-load state. The load detection is performed from the detection signal and the detection result of the engine speed detection sensor 97 for detecting the engine speed. In other words, the display calculation circuit 102 of the control device 100 calculates how much the engine speed has decreased at the operation position of the accelerator pedal 28 from the engine speed at the time of no load at the operation position of the accelerator pedal 28. The degree of load is displayed based on the magnitude of the deviation.

In the display calculation circuit 102, the display speed when the increase / decrease in the load displayed by the load meter 91 is represented by the LED 94 is set to be different depending on the degree of the load.
That is, in the large load range 94c in which the deviation calculated by the display calculation circuit 102 is large, the display operation of the red LED 94 is sensitively performed almost in synchronization with the load variation. In the middle load range 94b where the deviation is smaller than the large load range 94c, a delay circuit (not shown) is appropriately used so that the display operation of the yellow LED 94 is less sensitive than the display speed in the large load range 94c. The display speed is slowed down. Further, in the light load range 94a where the deviation calculated by the display arithmetic circuit 102 is the smallest, the display operation of the green LED 94 is insensitive to the display speed in the medium load range 94b and is the slowest. The display speed is further reduced through a delay circuit (not shown) as appropriate.

The display speed when the increase / decrease of the load displayed by the load meter 91 is represented by the LED 94 as described above is set to be different depending on the degree of the magnitude of the load. This is for the purpose of adjusting the load increase / decrease by operating the shift lever 21 of the hydrostatic continuously variable transmission 25.
That is, if the movement of the load meter 91 is too sensitive, it is difficult to perform the adjustment operation. With this structure, load fluctuations in the large load range 94c that are highly likely to be urgent are displayed sensitively and the load is large. The load fluctuations in the medium load range 94b and the light load range 94a, which are not so large, are displayed insensitively, making the display on the load meter 91 easier to see and making the adjustment operation easier.

  The possibility of applying the clutch operating device for a combine according to the present invention is not limited to the self-removing combine as shown in the embodiment, but can be applied to, for example, a full-throw-in type ordinary combine. Further, the present invention can be applied not only to grains such as rice and wheat but also to combines that harvest soybeans and rapeseed.

[Other Embodiment 1]
The drive device 7 according to the present invention is not limited to a single electric motor 70 or a cam drive type driven by a plurality of electric motors 70. A structure in which each actuator is operated separately using various actuators such as solenoids may be used.

[Second embodiment]
The load detection target displayed on the load meter 91 is not limited to that calculated from the accelerator set position and the engine speed as described above. For example, the load detection target is based on a comparison between the grain amount to be threshing processed and the vehicle speed. Alternatively, the load may be calculated for various factors that affect the engine speed, such as based on a comparison between the amount of exhaust straw and the vehicle speed.

DESCRIPTION OF SYMBOLS 3 Cutting and conveying apparatus 4 Threshing apparatus 5 Grain storage apparatus 20 Boarding operation part 30 Cutting clutch 50 Grain carrying out clutch 51 Glen tank 52 Grain carrying out auger 100 Control apparatus 101 Motor control circuit A Clutch operating apparatus

Claims (1)

A combine clutch operating device for operating a cutting clutch for turning on and off the driving of the cutting and conveying device and a grain carrying out clutch for turning on and off the driving of the grain storage device,
When the reaping clutch is in the engaged state, it prevents entry of the grain carrying out clutch, and when the reaping clutch is turned on in the engaged state of the grain carrying out clutch, the cereal carrying out is accompanied accordingly. A combine clutch operating device comprising control means for switching the clutch to a disengaged state.

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