JPH10178854A - Cutting part structure for combine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cutting device for which the rotary shaft center of a cutting blade driving part is turned to the front and back in the state of not accumulating cut straws and dust in a cutting frame. SOLUTION: The cutting blade base 80 of a cutting mechanism 11A is disposed and connected over three grass division frames 29c, 29b and 29a, a supporting frame (k) for attaching the cutting blade driving part 11B is disposed and connected over a first horizontal frame 93 in a horizontal direction for connecting the tip part of a single cutting main frame 9 and the rear end part of the right grass division frame 29a and the cutting blade base 80, the rear end part of the left grass division frame 29c and the tip part of the cutting main frame 9 are connected by a second horizontal frame 97 in the horizontal direction positioned in front of the first horizontal frame 93 and the cutting frame is constituted.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reaping structure of a combine, and more particularly to a technique for obtaining a reaping structure capable of smoothly driving a reaping device without any inconvenience.

[0002]

2. Description of the Related Art In a clipper-type reaper, a real open sho 58-
As shown in Japanese Patent No. 35824, a structure in which a cutting blade crank for driving a movable blade is rotated about a vertical axis is disclosed in Japanese Utility Model Laid-Open No. 63-163116 and Japanese Patent Laid-Open No. 7-322738.
There is a structure in which a cutting blade crank is rotated around a front-rear axis as disclosed in Japanese Unexamined Patent Publication (Kokai) No. H11-15095.

[0003]

Regardless of which of the above-mentioned shaft centers is employed, the crank-shaped driving rotating body is rotated, so that the clipper-type reaper has a large load fluctuation due to the driving or a rotational vibration. The operation tends to be non-smooth, for example, such as is likely to occur. Therefore, considering the smoothness of operation, in the structure in which the cutting blade crank is rotated around the vertical axis, the front-rear distance between the position where the crank presses and the movable blade changes with the rotation. The structure of rotating around has the advantage that the front-rear distance between the pressing action point and the movable blade does not change, and that the pressing action can be performed at a position close to the sliding portion of the cutting blade. That is, in terms of smooth operation, it seems better to adopt the front-back axis.

In view of the above-mentioned circumstances, the present invention has a disadvantage in that, when employing a cutting device in which the rotation axis of the cutting blade drive unit is oriented forward and backward, cutting straw and dust are liable to accumulate on the cutting frame constituting the cutting unit. It is intended to realize the state in which no problem occurs.

[0005]

[Means for Solving the Problems]

[Structure] A first invention is directed to a cutting device comprising a clipper-type cutting mechanism, a cutting blade drive unit for rotating a driving rotating body for driving the cutting mechanism about a longitudinal axis, and a cut grain. And a vertical conveying device for obliquely transferring the culm upward and laterally toward a rear feed chain. The leading end of a single reaping main frame and the rear end of the uncut side weeding frame, which are erected and connected to the body so as to be able to move up and down, are connected by a first horizontal frame facing left and right. A support frame for mounting the cutting blade drive unit is installed and connected between the frame and the cutting blade support frame, and furthermore, the rear end of the cutting side weeding frame and the front end of the cutting main frame are moved forward of the first horizontal frame. Located on the left Characterized that you have a frame cutting coupled with a second lateral frame orientation.

A second invention is characterized in that, in the first invention, the reaper main frame is supported at its root so as to be able to slide laterally with respect to the machine body.

In a third aspect based on the first or second aspect, the second horizontal frame includes a horizontal member for connecting the rear end of the cut side weeding frame and the support frame, and a left and right side of the horizontal member. It is composed of an oblique member connecting the middle and the leading end of the reaping main frame, and reciprocates right and left to a position above a space portion sandwiched between the oblique member and a horizontal member located in front of the oblique member. A vibration plate is disposed.

[Operation] As shown in FIG. 10, the reaping frame is generally composed of a reaping main frame 9 supported by an airframe, as disclosed in Japanese Utility Model Laid-Open No. 3-117417 and Japanese Patent Application Laid-Open No. 8-168314. To the left and right central portions of the horizontal frame 100 connecting the rear ends of the left and right weeding frames, and a plurality of weeding frames 29a, 29b,
A structure is employed in which the rear portions of 29c are connected to each other by a cutting blade frame 80. In this case, most of the cutting blade drive units have a vertical axis (see Japanese Utility Model Application Laid-Open No. 58-35824), and are disposed above the cutting mechanism.

Therefore, if the cutting blade driving portion 37 having the front-rear axis X is employed as in the first aspect, the cutting blade driving portion 37 is disposed at the rear portion of the cutting mechanism, so that the arrangement space is secured. Therefore, the position of the horizontal frame 100 is shifted rearward from the conventional one (see the phantom line in FIG. 10), but in such a case, the horizontal frame 100 is placed directly below the grain culm transport path by the vertical transport device 15. Is also located, so that the straw and garbage falling from the transported grain stems
It is not preferable because it is likely to accumulate on the sheet 00 and become a transport resistance or to develop a transport jam.

In the developed plan view shown in FIG. 10, the vertical transport device 15 and the horizontal frame 100 drawn by imaginary lines do not seem to interfere much, but the vertical transport device is inclined upward and backward. In fact, the front end is actually located in the vicinity of the mowing mechanism 11A in the front-rear direction, and the horizontal frame 100 of the imaginary line is located immediately below the grain culm transport path by the vertical transport device 15.

According to the configuration of the first aspect, the rear end of the left weeding frame and the front end of the cutting main frame are connected to each other by the second horizontal frame which is located forward of the first horizontal frame. Therefore, the position of the second horizontal frame in the front-rear direction
Since it can be made harder to shift backward than at least the conventional position, such as the same as or the same as the conventional horizontal frame, the second horizontal frame is moved out of the grain stalk transport path of the vertical transport device in plan view. Therefore, it is possible to eliminate or suppress the accumulation of cut straw, dust and the like on the second horizontal frame.

[0012] Then, as shown in FIG.
Weeding frame 29 on the left and right by horizontal frames 93 and 97
Since the c and 29a and the reaping main frame 9 are integrated, there is no shortage of frame strength as a reaping portion as compared with a conventional symmetrical shape. Further, since the cutting blade driving unit 11B is provided on the uncut side (right side) of the cutting mechanism 11A, for example, as shown in FIG.
Even if a rotating object such as a flywheel 92 is attached to the rear part, the rotating object 92 is located outside the vertical transport path in a plan view, and is preferable in that it does not easily cause winding of the straw.

According to the second aspect of the present invention, there is provided a rotation cutting mode in which the reaping unit is relatively leftward with respect to the machine body, and a middle cutting mode in which the reaping unit is relatively moved to the center side with respect to the machine body. In the case of employing a structure in which the mowing unit is horizontally slid with respect to the machine body so that the mowing unit can be selected, if the mowing frame according to the first aspect is used, the second horizontal frame located on the left side of the main mowing frame is moved forward. Regardless of the horizontal slide movement, the second horizontal frame is located outside the vertical transport path, which is convenient.

According to the third aspect of the present invention, the right side of the second horizontal frame is connected to both the support frame for supporting the cutting blade driving section and the main cutting frame, so that the main cutting frame in the cutting frame is used. A substantially triangular frame portion (space portion) is formed in the take-out portion, and the strength of the cutting frame can be sufficiently secured. However,
The substantially triangular frame portion is located below the horizontal transport device that collects the grain culm at the start end of the vertical transport device or below the start end of the vertical transport device, which increases the risk of foreign matter accumulation. Therefore, since a vibrating plate that reciprocates on the substantially triangular frame portion is provided, even if cut pieces, garbage, etc. fall, it is shaken down to the ground so that it does not accumulate, and since it is a plate, the vertical dimension is thin. Also, there is no hindrance to transportation such as contact with the transported grain.

[Effect] In the combine according to any one of the first to third aspects, the cutting blade drive unit having the front-rear rotation axis is advantageous in driving the movable blade, and there is no lack of strength and cutting. A reaping frame that does not cause accumulation of foreign matter such as straw can be constructed, and a reasonable reaping section structure can be obtained in which a structure that can smoothly drive the clipper-type reaping device can be laid out without any inconvenience.

The mowing portion structure according to the second aspect has an advantage that the mowing portion is also suitable for a configuration in which the mowing portion is slid laterally.

In the mowing portion structure according to the third aspect, the triangular frame portion is formed at the tip of the main mowing frame to improve the mowing frame strength. Can be eliminated at the same time and there is an advantage that it can be realized without inconvenience.

[0018]

FIG. 1 shows a side view of a self-removable combine harvester with two rows of cuts.
A cutting section 4 which is a pre-cutting device is connected to the front of the body 2 having a horizontal axis fulcrum P so as to be vertically oscillated by a hydraulic cylinder 3. A device 5, a control unit 6, a grain hopper 7, an engine 8, and the like are mounted.

As shown in FIG. 1 and FIG.
The reaping main frame 9 supported so as to be able to swing up and down around the horizontal axis fulcrum P, and a pair of right and left raising devices 10 arranged in parallel
a, 10b, a clipper-type cutting device 11 for cutting the root of the raised grain culm, a pair of left and right packers 12a, 12b that rake the cut culm into the middle of the cutting width, and diagonally forward from the top of each packer. A pair of left and right auxiliary transporting devices 13, 13 extended in a cantilever manner, a vertical transporting device 15 for transporting the cut culm to the upper rear and transferring it to the feed chain 14 of the threshing device 5 in a sideways posture are provided. I have.

The vertical transport device 15 is composed of a stock-holding and transporting mechanism 15a acting on the grain culm stock side and a head engaging transport mechanism 15b acting on the grain culm tip side. It is configured to be able to adjust the handling depth by swinging up and down around the center.

Next, the transmission system will be described. As shown in FIG. 8, the output of the engine 8 is branched into a working system and a traveling system, one branch power is transmitted to a threshing device 5 and a grain discharge mechanism of a grain hopper 7, and the other branch power is used for traveling. The transmission is transmitted to a hydrostatic continuously variable transmission (HST) 16 as a transmission for the vehicle, and after being appropriately shifted, decelerated by a transmission case 17 and transmitted to the left and right crawler traveling devices 1. Also,
The shift output of the hydrostatic continuously variable transmission 16 is branched in the transmission case 17, and a part of the branch power is transmitted to the reaper 4.

More specifically, as shown in FIG. 3, FIG. 5 and FIG. 8, a cutting portion support stand (not shown) erected at the front portion of the machine body 1 has a horizontal fulcrum serving as a swinging fulcrum of the cutting portion. A driving shaft 19 is horizontally mounted via a bracket (not shown) coaxially with the shaft fulcrum P, and the driving shaft 19 and the mowing portion drive shaft 21 of the transmission case 17 are connected to each other by the one-way clutch 22 and the belt transmission mechanism 2.
3, and only the forward rotation power of the branch transmission power is transmitted to the driving shaft 19 as the mowing unit driving force.

A base boss portion (not shown) of the mowing main frame 9 is supported so as to be slidable along the driving shaft 19, and the base boss portion can transmit torque to the driving shaft 19. In addition, a bevel gear 24 externally slidably fitted laterally and a bevel gear 25 meshing with the bevel gear 24 are mounted so as to be able to move laterally together with the base boss.
A pipe frame 27 that supports the front-rear transmission shaft 26 extends forward from the base boss, and a bevel gear 25 is connected to the rear end of the front-rear transmission shaft 26.

The structure of the mowing frame will be described. As shown in FIGS. 2 to 5, at the front end of the reaper main frame 9,
A first horizontal frame 93 formed by bending a rear part of the right weeding frame 29a is connected to the first horizontal frame 93. The first horizontal frame 93 includes left and right mounting plates (an example of a support frame k) for mounting and supporting the bevel gear case 37 for driving the cutting blade. ) The rear ends of 94 and 95 are connected. Three weeding frames 29a, 29
The cutting blades b and 29c are connected by a cutting blade stand (an example of a cutting blade support frame) 80, which will be described later, in the front and rear middle part, and the rear ends of the left and center weeding frames 29c and 29b and the left mounting plate 94 The transmission case 2 is connected by a tubular transmission case (an example of a horizontal member) 28 which is horizontally horizontal.
A transmission plate 28 is provided with a triangular plate (an example of an oblique member) 96 for connecting the front end 8 to the front end of the reaping main frame 9.
And the triangular plate 96 constitute a second horizontal frame 97.

The right mounting plate 95 is connected to the first horizontal frame 9.
3 and the cutting blade stand 80 are erected and connected, and reinforce the cutting blade stand 80 in the cutting blade driving portion. The lower portions of the left and right raising devices 10a and 10b are connected and supported by the front portions of the left and right weeding frames 29a and 29c. As shown in FIG. 3, the movable blade 82
The vibration plate 99 attached to is mounted. In other words, the vibrating plate 99 also reciprocates right and left with the driving of the mowing device 11, and functions to shake off the straw, dust and the like falling on the triangular plate 96 so as not to accumulate.

As shown in FIGS. 3 to 6, the front end of the pipe frame 27 and the upper part of the right raising device 10a are connected by a bevel gear case 30, and the front-rear transmission shaft 26 and the input shaft 31a of the raising device 10a are connected. And bevel gears are linked. In addition, a cylindrical case 33 in which a longitudinal intermediate transmission shaft 32 interlocked with a bevel gear is inserted into a front-rear transmission shaft 26 at a lower portion of the bevel gear case 30,
Further, an intermediate bevel gear case 34 is provided at a lower portion thereof. From the intermediate bevel gear case 34, a vertically-oriented transmission shaft 35, 36 is formed in a double transmission shaft between the lower and upper transmission cases 28.
Has been extended towards.

The vertical transmission shaft 35 on the inner side is the intermediate transmission shaft 32
The lower end of the vertical transmission shaft 35 is inserted into a bevel gear case 37 provided at the right end of the transmission case 28 so that the lower end of the transmission case 28
The transmission bevel gear mechanism 53 is connected to the lateral transmission shaft 38 inserted through the
Are linked by Further, the outer cylindrical transmission shaft 36 disposed outside is also interlocked with the lower end of the intermediate transmission shaft 32 in a decelerated state with a bevel gear, and the right packer 12a is attached to the lower portion thereof via a torque limiter 39. On the right side of the packer 12a, a right scraping conveyor belt 13a is wound around a driving pulley 40a provided on the upper part. Note that the right packer 12 to be driven is
This is a structure in which the packer 12b on the left side of FIG.

The left and right auxiliary transporting devices 13 include a driving pulley 4
0a, 40b and the driven pulley 49a, 49b disposed diagonally forward of the conveyor belt 1 with a locking projection.
3a and 13b are wound. Each driven pulley 49a, 49b is supported by a sheet metal support frame (not shown) which is an upper cover member for the auxiliary transport device 13.

A pipe frame 42 is erected from the left end of the transmission case 28 via a bevel gear case 41, and a horizontal transmission shaft 38 inserted into the transmission case 28 and a vertical transmission shaft 43 inserted into the pipe frame 42 are bevel gears. Are linked. In addition, the upper end of the pipe frame 42 and the upper part of the left raising device 10b are connected to the bevel gear case 44.
The vertical transmission shaft 43 inserted through the pipe frame 42 and the input shaft 31b of the raising device 10b are interlocked with the bevel gear.

In the bevel gear case 37 provided at the right end of the transmission case 28, the cutting blade drive shaft 45 extending in the front-rear direction and the inner vertical transmission shaft 35 are linked by a cutting blade bevel gear mechanism 52. The crank 46 provided at the front end of the drive shaft 45 is engaged with a vertical knife head 47 provided on the mowing device 11, and the mowing device 11 is reciprocated right and left at a constant stroke by the rotation of the cutting blade drive shaft 45. It is configured as follows.

The structure of the reaper 11 will be described. As shown in FIGS. 3 to 7, the mowing device 11 includes a mowing mechanism 11 </ b> A.
The cutting mechanism 11A includes a fixed blade 81 fixed to a cutting blade base 80 mounted over the weeding frames 29a, 29b, and 29c, and slides left and right with respect to the fixed blade 81. It comprises a movable blade 82 which is free, a knife head 47 fixed to the blade via an attachment stay 83 and the like. The cutting blade drive unit 11B includes a bevel gear case 37.
And a driving rotary body D supported by the driving rotary body D.

The knife head 47 is made of a plate material bent in a U-shape that is open rearward in a plan view, has a pair of passive surfaces 47a, 47a spaced apart in the left-right direction, and has a longitudinal axis X. Bearing 8 provided on drive rotating body D
4 is adapted so that its outer diameter just fits into the knife head 47. The driving rotary body D is formed by welding a cutting blade crank 46 to the tip of a cutting blade drive shaft 45, and a bearing 84 is rotatably supported on the cutting blade crank 46.

As shown in FIG. 4, the movable blade 82 and the mounting stay 83 are integrated with a rivet or the like together with a slider 85 that slides on the rear end surface of the fixed blade 81, and together with a knife clip 86 that presses the movable blade 82. The movable blade 82 is positioned up, down, up and down, and slides only to the left and right so that the slide plate 87 that is tightened and fixed slides on the rear end surface of the slider 85.

A recess 80a into which the knife head 47 enters the front is formed at the rear edge of the cutting blade stand 80, and the bearing 83, that is, the crank 46 is arranged so as to enter the recess. The axis X of the cutting blade drive shaft 45 is positioned substantially at the center of the knife head 47 in the vertical direction, and the movable blade 82 is positioned at the height level substantially in the vertical direction of the rotation trajectory of the crank 46. In addition, bearings 8 at the upper and lower limits of the rotational trajectory of crank 46
The vertical length of the knife head 47 is set to be slightly longer than the vertical distance between the four centers Y.

That is, the crank 46 is moved to the knife head 47
The front-rear spacing and the vertical spacing between the point of force pressing the passive surface 47a of the movable blade 82 and the point of application, which is the point of left and right sliding movement of the movable blade 82, are all short, and the movable blade 82 slides smoothly. It can be driven. Further, the crank 46 is formed in a disk shape having a weight portion 88 bulging in the axial direction on the opposite side of the mounting portion of the bearing 84 with respect to the rotation axis X, so that the vibration accompanying the rotation of the crank 46 is reduced. It is designed to function as a balancer.

The driving rotator D will be described in detail. As shown in FIGS. 6 and 7, the support shaft 89 of the bearing 84 for moving the movable blade and the balance weight 88 for reducing rotational vibration are integrally formed by casting to form the crank 46. Reference numeral 88 denotes a shape that protrudes outward and rearward as far as possible without contacting the bevel gear case 37, and is configured as a lightweight, efficient balancer having a high balance effect.

As shown in FIG. 4, the bevel gear case 37
The (cutting blade bevel gear mechanism 52) is disposed on the right side with respect to the entire reaping device 11, and is laid out at a position distant to the right from the grain conveying path of the vertical conveying device 15. Therefore, the flywheel 9 attached to the rear end of the cutting blade passive shaft 45
In No. 2, the cut straw, garbage, and the like falling from the culms conveyed vertically are unlikely to fall.

[Another Embodiment] As shown in FIG. 9, a first flywheel 92 is mounted on the cutting blade crank 46, and a rear portion of the cutting blade drive shaft 45 is projected from the bevel gear case 37.
A structure including the second flywheels 98 may be used. In this case, the second flywheel 98 is integrally formed with a balance weight 98a located on the opposite side of the axis X of the support shaft 89, so that the second flywheel 98 also functions as a balancer for reducing vibration. It is. Further, the first horizontal frame 93 is disposed on the rear side of the second flywheel 98 in a lying position.

[Brief description of the drawings]

FIG. 1 is an overall side view of a combine.

FIG. 2 is a plan view showing a front part of a reaper.

FIG. 3 is a longitudinal sectional side view showing an auxiliary transport device portion in a power transmission system of the reaper.

FIG. 4 is a plan view showing a cutting frame, a cutting device, and a vertical transport device.

FIG. 5 is a front view showing a part of a power transmission system of the reaper.

FIG. 6 is a longitudinal sectional side view showing a drive system of a right packer and a reaper.

FIG. 7 is a cross-sectional plan view showing a drive system of the reaper.

FIG. 8 is a diagram of a transmission system to a reaper.

FIG. 9 is a longitudinal sectional side view showing another structure of the mowing device drive unit.

FIG. 10 is a plan view showing a conventional mowing frame.

[Explanation of symbols]

 9 Cutting main frame 11 Cutting device 11A Cutting mechanism 11B Cutting blade drive unit 14 Feed chain 28 Horizontal member 29a, 29b, 29c Weeding frame 80 Cutting blade support frame 93 First horizontal frame 96 Diagonal member 97 Second horizontal frame k Support frame D Drive rotor X Rotation axis

Claims (3)

[Claims] 1. A cutting device comprising a clipper-type cutting mechanism, a cutting blade drive section for rotating a driving rotating body for driving the cutting mechanism around a front-rear axis, and moving the cut stalks rearward. And a vertical transport device for obliquely transporting the feed chain upward and laterally toward the feed chain of the combine, comprising: a cutting blade support frame that faces left and right in the cutting mechanism.
The leading end of a single cutting main frame supported by the machine so as to be able to move up and down and the rear end of the uncut weeding frame are connected by a first horizontal frame facing left and right. A support frame for mounting the cutting blade drive unit is installed and connected between the first horizontal frame and the cutting blade support frame, and further, a rear end portion of the cut side weeding frame and a front end portion of the cutting main frame. And a reaping frame structure of a combine, wherein the reaping frame is formed by connecting the second horizontal frame positioned forward of the first horizontal frame. 2. The harvester structure of a combine as claimed in claim 1, wherein the main frame of the mower is supported at its root so as to be able to slide laterally with respect to the body. 3. A horizontal member for connecting the second horizontal frame to a rear end of the cut side weeding frame and the support frame, a left and right middle of the horizontal member, and a front end of the cutting main frame. And a vibration plate that reciprocates left and right is disposed at an upper position of a space portion sandwiched between the diagonal member and a portion of the horizontal member located in front of the diagonal member. Certain claim 1 or 2
The reaping part structure of the combine according to [1].