JP2014000032A - Combine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To arrange a hydraulic infinite variable-speed drive unit for driving a threshing feed chain in a compact manner, and increase the support rigidity of the threshing feed chain.SOLUTION: A combine is provided with a threshing feed chain (8) disposed on one side of a handling chamber (7a) of a thresher (4) and a hydraulic infinite variable-speed drive unit (15) for driving the threshing feed chain (8). The hydraulic infinite variable-speed drive unit (15) is configured to drive the threshing feed chain (8) without driving a travel device (2) and a harvester (3). The hydraulic infinite variable-speed drive unit (15) is disposed in a space between the thresher (4) and a harvester support (5) for supporting the harvester (3) in a side view.

Description

  The present invention relates to a combine having a threshing feed chain for supplying cereal meal to a threshing device.

  Conventionally, a technique for driving a threshing feed chain of a threshing device by an HST (hydraulic continuously variable transmission) is known (for example, see Patent Document 1).

Japanese Patent Laid-Open No. 5-199812

  In the technique described in Patent Document 1, since the reaping device and the threshing feed chain are driven by the driving force output from the HST, the driving speed of the threshing feed chain with respect to the driving speed of the reaping device is changed. There is a problem that it is impossible to optimize the cereal supply rate to the threshing device.

  Moreover, since the output shaft of the gear case for transmitting the driving force from the HST to the threshing feed chain protrudes from the inner surface of the gear case toward the outside of the machine, the transmission mechanism extends from the gear case to the threshing feed chain. Cannot be placed compactly, and there is a problem that the size of the combine body increases.

  An object of the present invention is to eliminate the above-mentioned problem, and the next problem is to maintain a high transmission efficiency of the threshing feed chain by increasing the supporting rigidity of the HST.

The present invention has taken the following technical means to solve the above problems.
That is, the invention described in claim 1 includes a threshing feed chain (8) disposed on one side of the handling chamber (7a) of the threshing device (4), and a hydraulic stepless driving the threshing feed chain (8). The transmission is provided with a transmission (15), and the hydraulic continuously variable transmission (15) is configured to drive the threshing feed chain (8) without driving the traveling device (2) and the mowing device (3). The hydraulic continuously variable transmission (15) is a combine arranged in a space between the threshing device (4) and the cutting support (5) that supports the cutting device (3).

  According to a second aspect of the present invention, the hydraulic continuously variable transmission (15) is attached to a support frame (24) connecting the cutting support (5) and the front wall (4a) of the threshing device (4). The combine according to claim 1.

Invention of Claim 3 is a combine of Claim 1 or Claim 2 which has arrange | positioned the said hydraulic continuously variable transmission (15) in the site | part behind the front-end part of the threshing feed chain (8).
Invention of Claim 4 has arrange | positioned the said hydraulic continuously variable transmission (15) in the site | part below the threshing countershaft (12) constructed by the front side of the threshing apparatus (4). It is a combine as described in any one of claim | item 3.

  The invention according to claim 5 includes a gear case (19) that interlocks the hydraulic continuously variable transmission (15) and the threshing feed chain (8), and the threshing feed chain ( 8) The combine according to any one of claims 1 to 4, wherein the output shaft (21) projecting toward the side is arranged at a position above the hydraulic continuously variable transmission (15).

  According to the first aspect of the present invention, the threshing feed chain (8) can be driven at a speed different from that of the reaping device (3), and the hydraulic continuously variable transmission for driving the threshing feed chain (8). The device (15) can be arranged compactly.

  According to the invention described in claim 2, in addition to the effect of the invention described in claim 1, the hydraulic continuously variable transmission (15) is replaced with the cutting support (5) and the front wall (4a) of the threshing device (4). Is attached to a support frame (24) that connects to the hydraulic continuously variable transmission (15) to increase the support rigidity, and the transmission efficiency from the hydraulic continuously variable transmission (15) to the threshing feed chain (8). Can be increased.

  According to the invention described in claim 3, in addition to the effect of the invention described in claim 1 or claim 2, the hydraulic continuously variable transmission (15) is located behind the front end of the threshing feed chain (8). It is possible to prevent the accumulation of sawdust on the hydraulic continuously variable transmission (15).

  According to invention of Claim 4, in addition to the effect by the invention as described in any one of Claims 1 to 3, the hydraulic continuously variable transmission (15) is placed in front of the threshing device (4). The hydraulic continuously variable transmission (15) can be placed close to the front end of the threshing device (4) by placing it at a position below the threshing countershaft (12) installed, The continuously variable transmission (15) can be arranged in a compact manner.

  According to the invention described in claim 5, in addition to the effect of the invention described in any one of claims 1 to 4, the hydraulic continuously variable transmission (15) and the threshing feed chain (8) are interlocked. By arranging the output shaft (21) of the gear case (19) above the hydraulic continuously variable transmission (15), the output shaft (21) to the threshing feed chain (8) A distance can be shortened and the drive part of a threshing feed chain (8) can be comprised further compactly.

Combine side view Top view of the combine Schematic showing the power transmission mechanism of the main part of the combine Side view of the main part of the combine Side view of the main part of the combine Front view of the main part of the combine Front view of the main part of the combine Expanded side view of the main part of the combine

An embodiment of the present invention will be described with reference to the drawings.
The combine includes a cutting device 3 at the front of the machine body 1 that includes a traveling crawler (traveling device) 2 that cuts and conveys the planted cereal, and a rear part of the machine body that threshes and sorts the cereal that is conveyed and supplied from the cutting device 3. Threshing device 4, a grain tank 36 for temporarily storing the grains transferred from the threshing device 4, and a discharge device 37 for discharging the grains stored in the grain tank 36 to the outside of the machine.

The reaping device 3 is configured to be movable up and down with respect to the body 1.
That is, the horizontal transmission cylinder 34 having a horizontal transmission shaft is rotatably supported on the upper portions of the left and right cutting support bases 21a protruding upward from the body frame 1a of the body 1. Then, the cutting support frame 6 projecting forward from a portion of the horizontal transmission cylinder 34 on the side where the input pulley of the transmission shaft is present is supported by the cutting support frame 6 by rotating together with the horizontal transmission cylinder 34. The cutting device 3 moves up and down.

  The cereals harvested by the cutting blade device 37 of the reaping device 3 are transported by the transport device 30 having the stock source side transport device 31 and the tip side transport device 32 and taken over by the threshing feed chain 8 of the threshing device 4.

The threshing feed chain 8 is provided along a front and rear handling port 7 c formed on the left side of a handling chamber 7 a provided with a handling cylinder 7.
On the inner side (right side) of the conveying start end of the threshing feed chain 8, a cereal support 33 for supporting the tip side of the cereal from the lower side is arranged, and the rear end of this cereal support 33 Is facing the front surface of the handling chamber 7a, that is, the cereal supply port 7b formed in the front wall 4a of the threshing device 4.

Further, a pinch 51 urged by an elastic member on the threshing feed chain 8 side is arranged on the upper side of the conveying action area of the threshing feed chain 8.
The cereal grains handed over to the conveyance start end (front end) of the threshing feed chain 8 that overlaps the conveyance terminal end (rear end) of the conveyance device 30 in the side view in the front-rear direction, It is pinched by the chain 8 and the pinch 51, and the tip side part is supported by the wheat bran support body 33 and enters the handling chamber 7a from the grain feed port 7b, and moves backward while receiving the grain-removing action of the handling cylinder 7. Be transported.

  Next, a power transmission mechanism for transmitting power from the engine E to the threshing device 4 will be described. As shown in FIG. 3, the output shaft 11 of the engine E is interlocked with the threshing counter shaft 12 via a pulley and a belt. Further, the threshing counter shaft 12 is linked to a handle cylinder input shaft 14 from the threshing counter shaft 12 to the handle cylinder 7 via a pulley and a belt, and is hydraulically stepped through a counter pulley 13, an HST input pulley 17 and an HST transmission belt 18. It is linked to the HST input shaft 16 to the device (HST) 15. Further, the threshing counter shaft 12 is interlocked so as to transmit power to the processing cylinder 28, a swinging sorting shelf, and a sorting device such as a red pepper through a pulley and a belt.

  From the belt 55, the driving force of the engine E is transmitted to a continuously variable transmission different from the HST 15, and the cutting device 3 and the traveling crawler 2 are driven by the driving force output from the continuously variable transmission. Is done. That is, the driving speed of the reaping device 3 is linked to the traveling speed of the body 1 by the traveling crawler 2.

  The motive power input to the HST 15 is output from the HST output shaft 53 with the rotational speed steplessly changed in the process of being transmitted from the hydraulic pump in the HST 15 to the hydraulic motor. From the HST output shaft 53, the threshing feed chain 8 is rotationally driven through the reduction gear mechanism 20 in the reduction gear case (gear case) 19, the reduction output shaft (output shaft) 21, and the feed chain drive sprocket 22. doing. The feed chain drive sprocket 22 is interlocked with the deceleration output shaft 21 by being fitted into a coupling gear 21 a provided at the tip (outer end) of the deceleration output shaft 21.

  The HST 15 is located in front of the threshing device 4 and behind the reaping support base 5 that supports the reaping device 3. That is, it is arrange | positioned in the space formed between the front wall 4a of the threshing apparatus 4 and the cutting support stand 5 in side view.

And HST15 is arrange | positioned in the site | part ahead of this space, and the said threshing counter axis | shaft 12 is arrange | positioned in the site | part behind the space.
The threshing countershaft 12 is supported by a cylinder (support member) 23, and this cylinder 23 is supported on the front wall 4a by a stay 23a.

  The HST 15 is mounted and supported via a reduction gear case 19 on a support frame 24 that connects the connecting member 25 that connects the left and right cutting support bases 21a and the cylinder 23 of the threshing countershaft 12. The HST 15 is disposed near the right side (cylinder side) of the threshing feed chain 8 and is set at a position behind the start end of the feed chain (that is, the feed chain start end sprocket 9 and the tension sprocket 10).

  Although the HST 15 is detachably attached to the reduction gear case 19 attached to the support frame 24 in the illustrated example, the HST 15 may be configured to be directly attached to the support frame 24, or the reduction gear case. You may comprise 19 so that it may attach to another support member which protrudes from the body frame 1a side. According to this configuration, by attaching the reduction gear case 19 to the strong support member on the side of the body frame 1a, the load is shared between the HST 15 side and the reduction gear case 19 side. In addition to supporting the belt, it can be securely fixed even when pulled by a belt or chain.

  Further, the upper side of the reduction gear case 19 extends higher than the HST 15 and projects the deceleration output shaft 21 toward the threshing feed chain 8, and the feed chain is positioned higher than the HST 15. The drive sprocket 22 is linked and connected. That is, since the HST input shaft 16, the HST output shaft 53, and the deceleration output shaft 21 are arranged in a straight line in the vertical direction, the feed chain drive sprocket 22 is arranged while the HST 15 is arranged at a low position close to the body frame 1a. Is located higher, the bending of the threshing feed chain 8 can be reduced, the transmission efficiency can be improved, and the driving load can be reduced.

  The threshing feed chain 8 is configured to be rotatable around an open shaft 54 in the vicinity of its front end. Specifically, the chain rail 50 of the threshing feed chain 8, the feed chain drive sprocket 22, and the like support the support frame 52, and the front end of the support frame 52 rotates around the open shaft 54 of the left cutting support 5. It is possible to move.

Then, the feed chain drive sprocket 22 is detached from the coupling gear 21a by rotating the rear portion of the support frame 52 to the left side of the machine body.
Further, the HST 15 is configured to shift-control only the threshing feed chain 8 alone, but by operating the HST trunnion arm with the transmission motor 26, the threshing feed chain can be arbitrarily controlled to increase or decrease speed. The transmission motor 26 operates so that the threshing feed chain 8 is driven at an increased speed as the driving speed of the reaping device 3 increases.

  As shown in the figure, the belt transmission from the counter pulley 13 to the HST input pulley 17 can be easily performed by installing the HST 15 at a position below the threshing counter shaft 12, and the driving force of the HST 15 from the threshing counter shaft 12 Therefore, the hydraulic pump of the HST 15 operates only when the threshing device 4 is driven, and the no-load horsepower loss of the HST 15 is eliminated during non-working.

2 Traveling crawler (traveling device)
DESCRIPTION OF SYMBOLS 3 Cutting device 4 Threshing device 5 Cutting support stand 7a Handling room 8 Threshing feed chain 12 Threshing countershaft 15 HST (hydraulic continuously variable transmission)
19 Reduction gear case (gear case)
21 Deceleration output shaft (output shaft)
23 cylinder (support member)
24 Support frame

Claims (5)

  A threshing feed chain (8) disposed on one side of the chamber (7a) of the threshing device (4), and a hydraulic continuously variable transmission (15) for driving the threshing feed chain (8), The continuously variable transmission (15) is configured to drive the threshing feed chain (8) without driving the travel device (2) and the reaping device (3), and in a side view, the hydraulic continuously variable transmission ( The combine which arrange | positioned 15) in the space between the threshing apparatus (4) and the reaping support stand (5) which supports the reaping apparatus (3).   The combine of Claim 1 which attached the said hydraulic continuously variable transmission (15) to the support frame (24) which connects the said cutting support stand (5) and the front wall (4a) of a threshing device (4).   The combine of Claim 1 or Claim 2 which has arrange | positioned the said hydraulic continuously variable transmission (15) in the site | part behind the front-end part of the threshing feed chain (8).   4. The hydraulic continuously variable transmission (15) according to any one of claims 1 to 3, wherein the hydraulic continuously variable transmission (15) is disposed at a position below a threshing countershaft (12) installed on the front side of the threshing device (4). Combine as described.   An output provided with a gear case (19) interlocking the hydraulic continuously variable transmission (15) and the threshing feed chain (8) and projecting from the outer surface of the gear case (19) to the threshing feed chain (8) side. The combine according to any one of claims 1 to 4, wherein the shaft (21) is arranged at a position above the hydraulic continuously variable transmission (15).

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