JP2004248587A - Combine harvester - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a combine harvester including a conveying unit comprising a feeder housing revolvable at an inflection point and a conveyor equipped therein, intended to convey reaped grain culms more smoothly. <P>SOLUTION: The general-purpose combine harvester comprises the conveying unit 9. In this conveying unit 9, the endless conveyor equipped therein is composed of a front conveyor 41 and a rear conveyor 42, which are disposed in the longitudinal direction, and their speeds of conveyance are designed to be higher in the order of the front conveyor 41, the rear conveyor 42 and a 1st rotor( or a threshing cylinder 37 ) as the threshing rotator equipped in a threshing apparatus 18. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
TECHNICAL FIELD The present invention relates to a structure of a transport device for transporting grain stalks cut by a mowing device to a threshing device in a general-purpose combine.
[0002]
[Prior art]
Conventionally, in a general-purpose combine, a mowing device is provided at a front portion of a traveling body, a threshing device is provided at an upper portion of the body, and a culm cut by the mowing device is transported between the mowing device and the threshing device to the threshing device. Is provided. An operating unit for operating the combine is provided at the front of the aircraft.
[0003]
As the above-described transfer device, a transfer conveyor that is continuous from the rear portion of the mowing device to the entrance of the threshing device is provided, and the conveyer is provided inside a feeder housing (conveyer tube). A mowing device is connected to a front portion of the feeder housing, and a rear portion of the mowing device is supported by a housing in which a threshing device is installed so as to be vertically rotatable, so that the mowing device can be moved up and down.
In such a transport device, a technique is known in which a feeder housing is provided with a bent portion at an intermediate portion in the front-rear direction to reduce the size of the machine body and improve the transport state of grain culm. 1).
[0004]
In addition, the feeder housing bent as described above is divided into two front and rear parts, and the front feeder housing is configured to be rotatable at a bending point provided in the middle part between the front and rear, so that a compact body and good maneuverability can be obtained. Has also been proposed by the present applicant in Japanese Patent Application No. 2002-292915.
[0005]
[Patent Document 1]
JP-A-6-343326
[0006]
[Problems to be solved by the invention]
However, in the conveyor of the conventional transfer device, a pressing member is provided in the vicinity of the bent portion to maintain the tension of the conveyor, but a load is applied to the conveyor due to a change in tension when the conveyor is rotated, and the wear is reduced. There are concerns. In addition, in the vicinity of the bent portion of the transport path, for example, when the reaper is turned upward, grain culms to be transported are more likely to be clogged than in the straight portion.
SUMMARY OF THE INVENTION The present invention is directed to a feeder housing that is rotatable at a bending point and a transfer device including a conveyor provided therein to achieve better transfer of the harvested grain culm.
[0007]
[Means for Solving the Problems]
The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.
[0008]
That is, in claim 1, a reaping device that cuts the culm, a threshing device that threshes the culled culm, and a transport device that conveys the culm cut by the reaper to the threshing device, In a combine in which the transfer device is configured to be rotatable around a bending rotary shaft at an intermediate bending point provided in the middle of the transfer path, an endless conveyor provided in the transfer device is configured by a front conveyor and a rear conveyor. Are arranged in the front-back direction.
[0009]
According to a second aspect of the present invention, the rotating shaft for bending is also used as a rear support shaft of the front conveyor and a drive shaft of the front conveyor.
[0010]
In claim 3, the conveying speed of the rear conveyor is higher than the conveying speed of the front conveyor, and is lower than the conveying speed of the threshing rotary body provided in the threshing device.
[0011]
BEST MODE FOR CARRYING OUT THE INVENTION
Next, an embodiment of the invention will be described.
FIG. 1 is a side view showing an overall configuration of a combine according to a first embodiment of the present invention, FIG. 2 is a plan view showing the same overall configuration, and FIG. 3 is a side view showing a threshing / sorting unit. 4 is a side view showing the transport device, and FIG. 5 is a plan view of the transport device.
FIG. 6 is a side view showing an overall configuration of a combine according to the second embodiment of the present invention, FIG. 7 is a plan view showing the same overall configuration, and FIG. 8 is a side view showing a threshing / sorting unit. 9 is a perspective view showing a cabin frame.
[0012]
First, an overall configuration of a combine according to a first embodiment of the present invention will be described with reference to FIGS.
In the combine according to the present embodiment, a body frame 13 is provided on the crawler type traveling device 1, and a housing 33 that houses a threshing / sorting unit including a threshing device 18 and a sorting device 19 is provided on the body frame 13. An engine room 14 and the like for accommodating the engine 26 and the like are disposed at a rear portion of the housing 33.
A grain tank 30 for temporarily storing grains is provided on the housing 33, and a discharge auger 40 for discharging the grains stored in the grain tank 30 from the grain tank 30 is provided from the rear of the machine body to the front. It is prepared for.
[0013]
A mowing device 8 is disposed in front of the housing 33, and the rear end of the mowing device 8 and all the inlets of the threshing device 18 provided at the front upper portion of the housing 33 are communicated by a transport device 9. Is located approximately in the center of the aircraft.
Further, a cabin 17 containing a driver's seat 15, a steering handle 16, and the like is disposed above the transporting device 9, and the cabin 17 is disposed substantially in front of the right and left sides of the fuselage, and is capable of getting on and off from both left and right sides. Have been.
[0014]
The reaper 8 includes a transverse auger 3 supported and supported inside a platform 2 connected to a front portion of a feeder housing 10 which is a component of the transport device 9, and a lower front portion of the transverse auger 3. And a scraping reel 5 provided above the platform 2.
[0015]
The traverse auger 3 has a rotation axis in a direction orthogonal to the traveling direction, and the traverse auger 3 is provided with a grain stem cut by a rotation of the auger 3 into a feeder housing 10 connected to a substantially right and left rear portion of the platform 2. Is formed so as to be fed. Weeding plates 7, 7 are provided at the front ends on both left and right sides of the platform 2, and the rear part of the support arm 6 on which the reel 5 is suspended is supported on the left and right sides of the rear part of the platform 2. A power transmission mechanism including a belt, a pulley, and the like for driving the reel 5 to rotate is provided on one of the left and right sides. The reel 5 is raised and lowered by a hydraulic cylinder 29 as an actuator interposed between the support arm 6 and the platform 2.
[0016]
The transport device 9 includes a feeder housing 10 and endless front and rear conveyors 41 and 42 disposed in the feeder housing 10 in the front-rear direction.
A front end of the feeder housing 10 is communicated with a rear portion of the platform 2 in accordance with a feed end position of a screw of the transverse auger 3. Further, the rear end of the feeder housing 10 is communicated with an inlet 12 (FIG. 4) for the threshing device 18, and a second axis having a rotation axis in a direction substantially perpendicular to the traveling direction behind the inlet 12. One rotor 21 is provided, and the grain culm is forcibly conveyed to the first rotor 21 of the threshing device 18 by the front conveyor 41 and the rear conveyor 42.
[0017]
A rear portion of the feeder housing 10 is inserted into a front portion of a housing 33 that houses a threshing / sorting unit, and a hydraulic cylinder 32 is interposed between a lower surface of the front feeder housing 10 and the body frame 13, The reaping device 8 can be moved up and down.
[0018]
The threshing / sorting unit is disposed inside the casing 33, and is a threshing device 18 for threshing the grain stalks that have been mowed by the reaping device 8 and conveyed by the conveying device 9, and a grain that has been threshed by the threshing device 18. And a sorting device 19 for sorting.
[0019]
As shown in FIG. 3, the threshing device 18 includes a first rotor 21, a second rotor 22, and receiving nets 23 and 24, which are threshing rotary bodies, and is housed above the housing 33. The first rotor 21 and the second rotor 22 are configured to have substantially the same shape, and screws 21a and 22a having a plurality of teeth (not shown) are provided on the outer periphery of the cylinder. It is arranged in the front-back direction facing the direction.
[0020]
Under the first rotor 21 and the second rotor 22, receiving nets 23 and 24 are arranged, respectively. Above the first rotor 21 and the second rotor 22 are covered by upper covers 35 and 36, respectively. And a rear rotor chamber.
In addition, the rear portion of the right side of the receiving net 23 below the first rotor 21 has a gentle arc-shaped inclination formed in the front-rear and rear-high directions, and extends toward the tangential direction of the upper and outer peripheries of the second rotor 22 to communicate with each other. 23a is formed, and the rear end of the communication portion 23a extends to near the front end of the rotation trajectory of the second rotor 22. Further, a discharge port 24a is opened at the left rear portion of the receiving net 24.
[0021]
On the inner peripheral surface of the upper part of the upper covers 35 and 36 formed horizontally, dust-feeding valves 59 are provided at appropriate intervals in the left-right width direction. Are rotatably supported around a rotation fulcrum in the direction, and by rotating the dust feed valves 59, the grain stalks pass through the first rotor 21 and the second rotor 22. The moving time can be adjusted in accordance with the type and state of the grain culm, and the versatility of the threshing device 18 is enhanced.
[0022]
The screw 21a of the first rotor 21 is formed between the left end of the first rotor 21 and the left side of the communication part 23a, and the outer peripheral surface of the first rotor 21 in front of the communication part 23a has a radius of the first rotor 21. (FIG. 2) are formed. Similarly, the screw 22a of the second rotor 22 is formed between the right end of the second rotor 22 and the right side of the discharge port 24a, and the outer peripheral surface of the second rotor 22 in front of the discharge port 24a on the left side from the end of the screw 22a. . Are formed, and the waste (thicks) after threshing is sent by the feed blades 22b, 22b... (FIG. 2) and is discharged from the discharge port 24a.
[0023]
In such a configuration, when the grain stalk is transported from the feeder housing 10 to the input port 12, the grain stalk is threshed while being transported rightward by the rotation of the first rotor 21. Then, when reaching the right end of the first rotor 21, it is sent to the threshing space of the second rotor 22 from the communication portion 23 a formed in a gentle slope, and is threshed while being conveyed leftward by the rotation of the second rotor 22, When sent to the left end of the two rotors 22, it falls from the discharge port 24a.
[0024]
A guide plate 60 extends rearward and downward from the lower portion of the discharge port 24a, and is disposed between the upper portion of the rear portion of the guide plate 60 and the bottom surface of the engine room 14 to forcibly feed the culm rearward. 61 are provided.
The culm beater 61 has a left end that matches the left end of the outlet 24a, a right end of the culm beater 61 that extends further to the right than the right end of the outlet 24a, and a culm that has been discharged from the outlet 24a. Is conveyed backward and left widely. Behind the culm beater 61, a chopper-type spreader 62 is laid horizontally across the entire width at the rear end of the fuselage, and the straw discharged from the outlet 24a and conveyed to the spreader 62 by the culm beater 61 is The spreader 62 is cut by a plurality of hatchet-shaped blades and discharged to the field from the rear end of the machine.
[0025]
On the other hand, in the threshing / sorting unit, a sorting device 19 is provided below the threshing device 18.
As shown in FIG. 3, the sorting device 19 includes a flocking board 25, a swinging main body 20, a pre-fan 34, a Karin 27 that generates a sorting wind, and a first conveyor 28 that conveys the sorted first thing in the left-right direction. , A second conveyor 31 for transporting the second product, and the like, so that the thresh falling from the threshing device 18 can be sorted out.
[0026]
Next, details of the transfer device 9 according to the present invention will be described.
As shown in FIGS. 4 and 5, in the feeder housing 10, the front housing 70 at the front and the rear housing 71 at the rear are rotatably connected at a bending point 89. As a feature of the present invention, the conveyor housed in the feeder housing 10 is divided into a front conveyor 41 and a rear conveyor 42, which are divided into two near a bending point 89.
[0027]
The platform 2, which is a component of the mowing device 8, is connected to the front of the front housing 70, and the inside of the front housing 70 and the outlet of the platform 2 communicate with each other. A guide roller 74 that guides the front conveyor 41 is externally fitted to a front driven shaft 73 that is rotatably mounted on the front part of the front housing 70 so as to be rotatable in the horizontal direction.
[0028]
At the rear of the front housing 70, a support shaft 75, which is a front drive shaft and supports the rear portion of the front conveyor 41, is horizontally rotatively mounted on the support shaft 75 so as to be rotatable in the horizontal direction. Are externally fitted and fixed. Further, the support shaft 75 extends to both left and right outer sides from the front housing 70, and a sprocket 77 is provided on one side (the right side in the present embodiment) of the extended portion, and a sprocket 78 is provided on the other side (the left side in the present embodiment). Externally fitted and fixed. Support members 79, 79, which support a support shaft 75 pivotally supported by the front housing 70, are fixed to the housing 33 and rotatably supported by stays 80, 80.
[0029]
On the other hand, the rear housing 71 is arranged such that its front part is inserted into the rear part of the front housing 70 and its rear part is inserted into the housing 33. The bottom part of the rear housing 71 is constituted by a supply plate 81. ing. The supply plate 81 is a plate-shaped member that is fixed inside the housing 33 and is continuous from the rear end of the front housing 70 to the front and lower part of the first rotor 21, and is conveyed by the front conveyor 41 and the rear conveyor 42. The grain culm passes above the supply plate 81 and is guided to the first rotor 21.
[0030]
In the front part of the rear housing 71, a support shaft 43, which is a front support shaft of the rear conveyor 42, is horizontally slidably pivotable in the left-right horizontal direction, and guide rollers 46 are loosely fitted on the support shaft 43. One of the left and right sides (the left side in this embodiment) of the support shaft 43 extends outside the rear housing 71, and the sprockets 44 and 45 are integrally fitted to the extended portion. At the rear of the rear housing 71, a rear drive shaft 82 is rotatably mounted horizontally in the left and right direction, and sprockets 90 are externally fitted and fixed to both sides of the rear drive shaft 82 in the rear housing 71. One of the left and right sides of the rear drive shaft 82 (the same side as the extended portion of the support shaft 43) extends outside the rear housing 71, and the sprocket 83 and the pulley 84 are externally fitted and fixed to the extended portion. ing.
[0031]
Therefore, the power from the engine 26 is transmitted to the rear drive shaft 82 by a transmission belt (not shown) wound around the pulley 84 via a clutch or the like, and further, the sprocket 83 of the rear drive shaft 82 and the support shaft 43. The rotation of the rear drive shaft 82 is transmitted to the support shaft 43 by the chain 85 wound around the sprocket 44, and is supported by the sprocket 45 of the support shaft 43 and the chain 47 wound around the sprocket 78 of the support shaft 75. The rotation of the shaft 43 is transmitted to the support shaft 75. Then, the power is transmitted to the support shaft 75 by a chain 88 wound around a sprocket 77 of the support shaft 75 and a sprocket 87 externally fitted to a transmission shaft 86 rotatably supported on the front side of the front housing 70. Power is transmitted to the mowing device 8 by the transmission shaft 86, and the cutting blade 4, the lateral feed auger 3, and the like are driven.
In addition, the mechanism of the power transmission of the front conveyor 41 and the rear conveyor 42 in the transport device 9 of the present embodiment is one example of the embodiment and is not restrictive.
[0032]
The rear drive shaft 82 is disposed inside the housing 33 and near the input port 12 of the threshing device 18. Therefore, the grain stalks cut by the cutting device 8 are directly conveyed to the inlet 12 of the threshing device 18 by the front conveyor 41 and the rear conveyor 42 provided in the conveyance device 9.
[0033]
The front conveyor 41 includes left and right chains 41a, 41a wound around guide rollers 74 and guide rollers 76, 76 of a support shaft 75, which are externally fitted to the front driven shaft 73, and left and right chains 41a, 41a. . Are provided between the slats 41b. Similarly, the rear conveyor 42 also includes guide rollers 46 of the support shaft 43, left and right chains 42a wound around the sprockets 90 externally fitted to the rear drive shaft 82, and left and right chains 42a. Are provided between the chains 42a. The slats 42b are provided between the chains 42a.
[0034]
In the feeder housing 10 configured as described above, the rear housing 71 is fixed, and the front housing 70 is rotatable about the support shaft 75. That is, the rotation shaft separately provided at or near the position of the support shaft 75, which is the rear support shaft of the front conveyor 41, is used as a bending rotation shaft, and the entire feeder housing 10 can be bent in the front-rear halfway. ing. The position of the support shaft 75 and the vicinity thereof are defined as bending points 89.
An end of a piston rod 32a of a hydraulic cylinder 32 as an actuator is supported on a stay 70a provided on the lower surface of the front housing 70, and the base of the piston rod 32a is supported by the hydraulic cylinder 32 supported on the body frame 13. The front housing 70 is driven up and down by expansion and contraction of the rod 32a. The lowermost position of the front housing 70 is a position that is substantially in line with the rear housing 71, and the uppermost position can be rotated as a position just before contact with the cabin 17 disposed above the feeder housing 10. It is.
[0035]
The front conveyor 41 is wound around the guide roller 74 loosely fitted on the front driven shaft 73 and the guide rollers 76 on the support shaft 75, and the guide roller 46 on the support shaft 43 and the rear drive shaft 82 The rear conveyor 42 is wound around the sprockets 90 fitted to the outside. The space between the lower part of the front conveyor 41 and the rear conveyor 42 and the lower surface of the box-shaped feeder housing 10 is a conveying path for grain culm.
[0036]
In the conveying route of the grain culm, the slats installed on the respective conveyors reach the portion between the front conveyor 41 and the rear conveyor 42 when the front conveyor 41 and the rear conveyor 42 rotate, respectively. An auxiliary body 49 having a mountain shape in a side view is provided on the lower surface of the feeder housing 10, that is, on the lower surface of the rear housing 71 in the left-right direction in order to fill the empty space.
The auxiliary body 49 has a length in the left-right direction longer than at least the slats provided on the front conveyor 41 and the rear conveyor 42, respectively, and has a shape that does not hinder the rotation of the feeder housing 10 at the bending point 89. And is provided at a position where the rotation is not hindered.
[0037]
That is, by providing the auxiliary body 49, the cut culm does not remain without being conveyed between the front conveyor 41 and the rear conveyor 42, that is, in the vicinity of the bending point 89, in the conveying path of the culm. It has a structure.
[0038]
Instead of providing the auxiliary body 49, the shape of the front housing 70 and the rear housing 71 is changed, and the transport path formed by the front housing 70 and the rear housing 71 is the same as the state where the auxiliary body 49 is provided. May be formed.
[0039]
The guide rollers 76 and 76 externally fitted to the support shaft 75 located at the bending point 89 and the guide rollers 46 and 46 externally fitted to the support shaft 43 are not sprockets but rollers. This is to prevent the culms to be conveyed from meshing with each other at the bending point 89 where the gap between the conveying surface and the front conveyor 41 and the rear conveyor 42 is small.
[0040]
In the transporting device 9 configured as described above, the conveyor disposed in the feeder housing 10 is divided into a front conveyor 41 and a rear conveyor 42, and the rear is fixed from a bending point 89 and the front is the bending point. It rotates about a support shaft 75 provided at 89 and supporting the rear side of the front conveyor 41. That is, the transfer path of the transfer device 9 is bent at the bending point 89.
The support shaft 75, which is a turning shaft for bending, is also a turning fulcrum for raising and lowering the reaping device 8, and the turning fulcrum of the reaping device 8 is more forward than when the transport device 9 is not configured to be bendable. Will be located.
[0041]
In the present embodiment, the support shaft 75 has a function as a connecting shaft between the front housing 70 and the rear housing 71 and a function as a rear support shaft of the front conveyor 41. The pivot shaft 75 serves as a pivot for raising and lowering. A connecting shaft for connecting the front housing 70 and the rear housing 71 is provided separately near the bending point 89, and this connecting shaft is used as a bending shaft for the feeder housing 10, that is, the cutting. It can also be used as a lifting fulcrum of the device 8.
[0042]
As described above, in the transport device 9, the conveyor contained in the feeder housing 10 is divided into the front conveyor 41 and the rear conveyor 42, so that a change in the tension or looseness of the conveyor caused by the rotation of the feeder housing 10 at the bending point 89. Can be prevented, the tension of each conveyor can be kept constant, and the amount of movement of the conveyor due to the rotation of the feeder housing 10 can be reduced. Therefore, the load applied to the conveyor can be reduced and it can withstand long-term use.
[0043]
In addition, it is possible to bend at a bending point 89 located in the middle of the transport path, and by disposing a lifting fulcrum of the mowing device 8 at the bending point 89, the height of the lifting fulcrum of the mowing device 8 is increased. Since it is possible to arrange the height position in front and below compared with the conventional structure, even if the height difference between the reaper 8 and the threshing device 18 is large, it is provided above the lifting pivot. Cabin 17 can be arranged without being raised from the ground.
[0044]
In addition, since the transport device 9 bends at a bending point 89 provided in the middle of the transport device 9 in the front and rear direction, the bending point 89 is used as a pivotal fulcrum for raising and lowering the reaper 8 so that the lifting device can be rotated. The moving fulcrum can be positioned more forward than in the prior art, and the distance from the lifting pivot of the reaper 8 to the reaper 8 can be shortened. Therefore, the turning radius of the mowing device 8 is reduced, so that the space required for vertically moving the mowing device 8 is omitted, and the body can be made compact.
[0045]
Further, since the rear end position of the transport device 9 and the pivoting fulcrum for raising and lowering the mowing device 8 do not necessarily have to be at the same position, the degree of freedom of the rear end position of the transport device 9 is increased, and the housing in which the threshing device 18 is housed. The rear end of the conveying device 9 can be arranged inside the body 33 and just before the inlet 12 to the threshing device 18.
[0046]
Incidentally, the sprocket 45 externally fitted to the extended portion of the support shaft 43 that supports the front portion of the rear conveyor 42 described above has a smaller number of teeth than the number of teeth of the sprocket 78 externally fitted to the support shaft 75. Used. By doing so, the reduction ratio of the support shaft 75 to the rotation speed of the support shaft 43 decreases. That is, the transport speed of the front conveyor 41 is lower than the transport speed of the rear conveyor 42. Further, the transport speed of the rear conveyor 42 is adjusted so as to be lower than the transport speed (peripheral speed) of the first rotor 21 which is a threshing rotary body.
In other words, if the transport speed of the front conveyor 41 is v1, the transport speed of the rear conveyor 42 is v2, and the transport speed (peripheral speed) of the first rotor 21 is v3, the speed relationship satisfies v1 <v2 <v3. I have.
[0047]
By adopting such a structure, the transport speed increases as it goes to the downstream side of the front conveyor 41, the rear conveyor 42, and the first rotor 21 (toward the threshing device 18). The accumulated culm is less likely to stay in the middle of the transport path, so that clogging of the cereal stem or the like in the transport device 9 can be prevented, and a smoother transport operation can be performed.
[0048]
If the front conveyor 41, the rear conveyor 42, and the first rotor 21 have a structure that satisfies the above-described speed relationship, the sprockets 45 and 78 and the chain 47 may be two pulleys and belts having different outer diameters. A configuration in which a transmission gear is provided between the conveyor 41 and the rear conveyor 42 is also possible.
[0049]
Next, a combine according to a second embodiment of the present invention will be described.
First, the configuration of the combine according to the present embodiment will be described with reference to FIGS. Members and devices having substantially the same form and function as those of the first embodiment are denoted by the same reference numerals, and description thereof is omitted.
[0050]
In the present embodiment, the combine threshing device 18 has a body having a handling cylinder 37 whose axial direction is the front-rear direction, and the transfer device 9 according to the present invention can be applied to this combine.
As shown in FIG. 8, in the combine according to the present embodiment, in the threshing / sorting unit, a sorting device 19 is provided below the threshing device 18, and a screw-type impeller is provided in the threshing device 18 in the front-rear direction. A handling cylinder 37, which is a threshing rotating body attached to the surface, is arranged to thresh the grain stalk. In addition, a sorting device 19 is disposed below the handling cylinder 37 via a receiving net 38, and the processed material that has been threshed by the threshing device 18 is sorted.
[0051]
The sorting device 19 includes a swing main body 20 having a chaff sheave 48, and a Karamin 27, a first conveyor 28, a second conveyor 31 and the like, which are arranged below the swing main body 20 on the flow tray 25 from the front side in that order. It is configured to sort out the grains leaking from the receiving net 38.
Further, a chopper-type spreader 62 having a plurality of cutting blades planted on a rotating shaft is disposed below the rear part of the handling cylinder 37, and the culms transferred to the rear of the handling chamber by the handling cylinder 37 are finely cut. Later, it is discharged outside the fuselage.
[0052]
The transfer device 9 of the present invention can be applied to a combine having a threshing / sorting device having such a configuration, and the same effect can be obtained.
Also in this embodiment, as in the first embodiment, the transport speed of the front conveyor 41 is v1, the transport speed of the rear conveyor 42 is v2, and the transport speed (peripheral speed) of the handling drum 37 as a threshing rotary body is v3. Then, the speed relationship satisfies v1 <v2 <v3.
[0053]
Next, the slide frame 50 provided below the cabin 17 will be described.
As described above, due to the structure of the transfer device 9 according to the present invention, even if the cabin 17 is arranged at the same height position as the conventional combine in which the transfer device and the cabin are arranged side by side, the cabin 17 is located below the cabin 17. The transfer device 9 is provided without interfering with the transfer device 17. That is, the grain stalks cut by the cutting device 8 pass under the cabin 17 and are supplied to the input port 12 of the threshing device 18 without changing the total length and height of the fuselage as compared with the conventional combine. Can be configured. Therefore, the effect that the arrangement of the cabin 17 in the combine can be easily and widely provided is obtained.
[0054]
Based on such an effect, a description will be given of a slide frame 50 in which the cabin 17 can be moved in the left-right direction with reference to FIG.
The slide frame 50 is slidable in the left and right directions on two support frames 53 and 53 suspended in the left and right directions on the step frames 51 and 51 which are support members fixed to the front part of the body frame 13. It is provided in.
The step frames 51, 51 are substantially the same as the frames 51a, 51a extending substantially horizontally in the longitudinal direction of the fuselage, and the frames 51b, 51b extending diagonally upward and forward from the front of the fuselage frames 13, 13. It is assembled in a substantially triangular shape in a side view with a rear frame (not shown), and the support frames 53 are erected in the left-right direction with a cylinder 52 interposed between the frames 51a.
[0055]
The slide frame 50 includes cylindrical sliding pipes 54, a support plate 55 erected in the longitudinal direction of the body between the sliding pipes 54, 54, and a piston fixed to the support plate 55. And a cylinder 52 having a rod 52a.
[0056]
The sliding pipes 54 are slidably fitted to support frames 53 suspended on the frames 51a 51a, and a support plate 55 is provided between the sliding pipes 54. It is erected. That is, the sliding pipes 54 and the support plate 55 have a substantially H-shaped configuration in plan view, and they have a structure that can slide integrally with the support frames 53.
On the upper surface of the sliding pipes 54, mounting bodies provided with vibration dampers 56, such as rubber, are uniformly arranged and fixed in the longitudinal and lateral directions of the body, respectively. The lower portion of the cabin 17 is fixed so that the cabin 17 can be attached to the cabin 17 while preventing transmission of vibration.
[0057]
One side (base) of the cylinder 52 is fixed to one of the frames 51a of the step frame 51 (the right side in this embodiment) in the front and rear substantially central portion, and the other side, that is, the cylinder 52 The end of the piston rod 52a is fixed to the other front and rear substantially center of the frames 51a. In other words, the cylinder 52 is interposed between the support frames 53 and 53 so as to extend and contract in the lateral direction of the machine.
[0058]
That is, the cabin 17 fixed on the slide frame 50 via the vibration insulators 56, 56... Usually has a fixed position substantially at the center of the body, but in a state where the discharge auger 40 is moved upward. As shown by a two-dot chain line in FIGS. 2 and 7, the cylinder 52 is slidable in the left-right direction by the expansion and contraction of the piston rod 52a.
The left and right sliding operation of the cabin 17 can be remotely controlled by an operator in the cabin 17 by interposing an actuator (not shown) or the like. That is, the worker can move the cabin 17 left and right while riding the machine and performing work.
[0059]
Further, due to the structure of the transfer device 9 according to the present invention, the transfer device 9 is disposed below the cabin 17 without interfering with the cabin 17. That is, the cabin 17 can be slid right and left without changing the height position of the cabin 17 with respect to the conventional combine. Therefore, the cabin 17 can be set at any position within the slidable range of the cabin 17 on the slide frame 50.
The sliding range of the slide frame 50 can be adjusted by changing the width of the step frames 51, 51 and the length of the slide pipes 54. Further, in the present embodiment, the slide frame 50 is provided on the side of the step frames 51, 51. However, the slide frame 50 can be attached to the cabin 17 and the cabin 17 can be slid.
[0060]
With such a structure, the cabin 17 can be moved in accordance with the work on the ridge in the turning direction in a general-purpose combine that can perform clockwise and counterclockwise mowing operations. Work can be performed at a position where the weeding boards 7, 7 provided on both the left and right sides can be more easily seen. Therefore, even when the crop is in the laid-down state, etc., it is possible to perform a uniform reaping operation and reduce the intake loss.
[0061]
The discharge auger 40 has a pivot point at the rear end of the fuselage. When the discharge auger 40 is rotated while being moved upward, a blind spot occurs, but the cabin 17 is moved right and left. Thereby, the blind spot at the time of discharge at the position where the discharge auger 40 is rotated can be reduced.
Further, even when the cabin is backed, if the cabin is slid to the right or left, it is possible to check the rear by directly observing the cabin, thereby improving safety. That is, the visibility and the workability can be improved over the entire work in the combine, and the stress of the worker due to the work for a long time can be reduced.
The shape and the like of the slide frame 50 are not limited to the present embodiment, and may be any structure as long as the cabin can slide in the left-right direction. Applicable.
[0062]
【The invention's effect】
The present invention is configured as described above, and has the following effects.
[0063]
That is, as shown in claim 1, a reaping device that reaps the culm, a threshing device that threshes the reaped cereal culm, and a transport device for transporting the culm reaped by the reaper to the threshing device, In a combine where the transfer device is configured to be rotatable around a bending rotary shaft at an intermediate bending point provided in the middle of a transfer path, an endless conveyor provided in the transfer device includes a front conveyor and a rear conveyor. However, since these are arranged in the front-rear direction, it is possible to prevent a change in the tension of the conveyor caused by the rotation of the conveyor at the bending point, and to keep the tension of each conveyor constant. Therefore, the load applied to the conveyor can be reduced and it can withstand long-term use.
[0064]
As described in claim 2, since the turning shaft for bending also serves as the rear support shaft of the front conveyor and the drive shaft of the front conveyor, the turning shaft for bending, which is a turning fulcrum for raising and lowering the reaper, is used. It becomes possible to be disposed forward and downward from the rear end of the transfer device, and even when the height difference between the mowing device and the threshing device is large, the operating unit provided above the lifting fulcrum is It can be arranged without increasing the height, and the degree of freedom of arrangement of the driving unit is increased. Further, the degree of freedom of the rear end position of the transport device is also increased. Further, since the turning radius of the mowing device can be shortened, a space required for vertically moving the mowing device is omitted, and the body can be made compact.
[0065]
As shown in claim 3, since the transport speed of the rear conveyor is faster than the transport speed of the front conveyor, and less than the transport speed by the threshing rotary body provided in the threshing device, the front conveyor, the rear conveyor, Since the transport speed increases as the threshing rotary body or the first rotor or handling drum and the transport path downstream (threshing apparatus side), the grain stalks cut by the reaper stay in the transport path. This reduces the occurrence of clogging of cereal stems and the like in the transfer device, and enables a smoother transfer operation.
[Brief description of the drawings]
FIG. 1 is a side view showing an overall configuration of a combine according to a first embodiment of the present invention.
FIG. 2 is a plan view showing the overall configuration.
FIG. 3 is a side view showing the threshing / sorting unit.
FIG. 4 is a side view showing the transport device.
FIG. 5 is a plan view of the same.
FIG. 6 is a side view showing an overall configuration of a combine according to a second embodiment of the present invention.
FIG. 7 is a plan view showing the overall configuration.
FIG. 8 is a side view showing the threshing / sorting unit.
FIG. 9 is a perspective view showing a cabin frame.
[Explanation of symbols]
8 Harvester
9 Transport device
17 cabins
18 Threshing equipment
21 First rotor
37 Handling cylinder
41 Front conveyor
42 Rear conveyor
50 slide frames
75 spindle
89 Bending point

Claims (3)

A harvesting device for cutting grain culms, a threshing device for threshing the harvested grain culm, and a transport device for transporting the grain stalks harvested by the mowing device to the threshing device, comprising the transport device in the middle of the transport route. In the combine configured to be rotatable with the bending rotary shaft at the provided intermediate bending point, the endless conveyor provided in the transfer device is configured by a front conveyor and a rear conveyor, and these are arranged in the front-rear direction. A combine characterized in that: The combine according to claim 1, wherein the bending rotation shaft is also used as a rear support shaft of the front conveyor and a drive shaft of the front conveyor. The combine according to claim 1 or 2, wherein the transfer speed of the rear conveyor is higher than the transfer speed of the front conveyor, and less than the transfer speed of the threshing rotating body provided in the threshing device. .

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