JP2006075128A5 - - Google Patents

Description

Threshing part structure of thresher

  The present invention relates to a threshing machine in which a front handling cylinder and a rear handling cylinder supported rotatably on the rear end portion of the rotation support shaft of the front handling cylinder are rotatably driven in a handling chamber. This relates to the structure of the threshing part.

  As the threshing portion structure, as shown in, for example, Patent Document 1, for example, a first barrel 3A (corresponding to a front barrel) and a rotary cylinder shaft 24 at the rear portion of a rotary shaft 23 that supports the first barrel 3A. There is one provided with a second handling cylinder 3B (corresponding to a rear handling cylinder) supported so as to be relatively rotatable through the.

JP-A-11-75508 ([0013], [0015] stages, FIG. 2)

This type of threshing machine drives the rear barrel at a higher speed than the front barrel so as to suppress, for example, leftovers, small loss, cracks and scraps, and the drum outer diameter of the rear barrel. It is possible to adjust. For this reason, the rear handling cylinder is deformed or damaged, or becomes incompatible with the threshing target cereal, and it is relatively easy to repair, replace, or adjust the rear handling cylinder.
To remove and install the rear barrel, the front barrel is also removed from the threshing machine together with the rear barrel so that the rear barrel can be removed. If it must be detached from the shaft, there is a problem that labor and labor are required for the work of detaching the front barrel from the threshing machine.

  The objective of this invention is providing the threshing part structure of the threshing machine which can remove | desorb a rear part barrel quickly and easily.

According to the first aspect of the present invention, the front handle cylinder and the rear handle cylinder supported in a relatively rotatable manner at the rear end portion of the rotation support shaft of the front handle cylinder can be driven and rotated in the handling chamber. In the threshing part structure of the provided threshing machine, the rear handling barrel can be divided into a rim member that is externally fitted so as to be rotatable relative to the rotating support shaft, and a drum plate that is detachable from the outer periphery of the rim member. The drum plate is configured to be divided into a plurality of divided drum plates in the circumferential direction of the rear barrel.

Chi words, by assembling the divided drum plate against Trim member, becomes the drum plate in the finished state, the result, after the rotation shaft of the front threshing drum rear threshing drum is turned completed state It will be in the state attached to the edge so that relative rotation was possible. By removing each divided drum plate , the rear handling cylinder is disassembled and detached from the rotating spindle. As a result, the rear barrel can be detached from the rotary spindle or assembled to the rotary spindle, and even if the front barrel is left attached to the threshing machine, only the rear barrel is attached to the front barrel. It can be mounted in a predetermined mounting state supported relative to the rear end portion of the rotating spindle so as to be relatively rotatable, or can be detached from this mounting state.

Therefore, according to the first aspect of the invention, when performing the work of repairing, exchanging, and adjusting the rear handling cylinder, the rear handling cylinder is detached and removed without removing the front handling cylinder from the threshing machine, and the work is performed efficiently and easily. be able to.

Embodiments of the present invention will be described below with reference to the drawings.
As shown in FIG. 1, the stocker side of the harvested grain culm is sandwiched and conveyed rearwardly by the threshing feed chain 2 that is rotatably driven outside the threshing machine body 1, and the tip side of the harvested grain culm Is threshed by the front handling cylinder 20 and the rear handling cylinder 30 that rotate side by side in the front-rear direction of the threshing machine body, and the threshing drainer is fed to the rear end of the handling room 3 by the threshing feed chain 2. The threshing waste straw carried out from the dust feed port 4 located in the chamber 3 is inherited from the threshing feed chain 2 by the waste straw carrier chain 5 and transferred to the rear side of the threshing machine body and transferred to the outside of the threshing machine body 1. The threshing unit is configured to discharge. While the processed threshing product dropped from the receiving net 6 of the handling chamber 3 is received by a swing sorting device 7 positioned below the threshing portion so as to be able to drive and swing, this swing sorting device 7 is transported backward in the threshing machine body. And the sorting wind supplied by the Kara 8 to sort the grain and dust, drop the grain from the swinging sorter 7, and suck the dust together with the sorting wind by the dust exhaust fan 9 to the outside of the threshing machine 1 The sorting unit is configured to discharge the water. The fine grains dropped from the rocking sorter 7 are received by the No. 1 screw conveyor 11 and conveyed to the lateral outside of the threshing machine 1. The untreated grains dropped from the rocking sorter 7 are picked up by the No. 2 screw conveyor 12 and threshed. Conveyed to the lateral outer side of the machine body 1, configured to discharge unprocessed grains from the No. 2 screw conveyor 12 into the threshing machine body by a reduction conveyance device (not shown) and reduce it to the starting end side of the swing sorting device 7. Therefore, a threshing machine for combine is configured.

  The threshing portion will be described in more detail. As shown in FIGS. 1 and 2, the front barrel 20 is disposed on the front side of the threshing machine with respect to the dust feed port 4 of the handling chamber 3. The front handling cylinder 20 penetrates the front handling cylinder 20 and is connected to the front handling cylinder 20 through a rotating support shaft 21 facing the front and rear of the threshing machine body in a front-rear direction. The side plate 15 and the rear side plate 16 are rotatably supported. The rear handling cylinder 30 is disposed so as to be positioned above the dust feeding port 4 of the handling chamber 3. The rear handle cylinder 30 is supported relative to the rear end portion of the rotary support shaft 21 of the front handle cylinder 20 via a cylindrical support shaft 31 positioned at the shaft core portion of the rear handle cylinder 30.

The length L of the rear handling cylinder 30 in the longitudinal direction of the threshing machine body is equal to or close to the length of the dust feed port 4 in the longitudinal direction of the threshing machine body. The drum outer diameter D1 of the rear threshing drum 30 than the drum outer diameter D2 of the front threshing drum 20 to a small west (eg the drum outer diameter D2 of the front portion threshing drum 20 if about 424.6Mm, drum rear threshing drum 30 The outer diameter D1 is about 324.6 mm), and the rear handle 30 is set so that the outer diameter of the rear handle 30 at the tip of the teeth is equal to or substantially equal to the outer diameter of the front handle 20 at the tips of the teeth. The length that protrudes from the rear handle drum circumferential surface of the tooth handle 32 is made larger than the length that protrudes from the front handle drum peripheral surface of the tooth handle 22 of the front handle 20.

As shown in FIG. 2, a self-propelled machine body is connected to an input pulley 40 that is provided at an end protruding from the front plate 15 of the rotary support shaft 21 of the front handle cylinder 20 to the outside of the handling chamber via a transmission belt 41. Is configured such that the engine output is transmitted from a driving part (not shown) of the motor and the rotary support shaft 21 is driven, so that the front handling cylinder 20 is rotated around the axis P1 of the rotary support shaft 21 in the front-rear direction of the threshing body. Is driven to rotate. An input provided on the front end portion of the rotary transmission shaft 42 which is positioned parallel to the rotary support shaft 21 and is rotatably supported by the front plate 15 and the rear plate 16 on the lateral side of the front handle cylinder 20. The engine output is transmitted to the pulley 43 via the transmission belt 41, and the driving force of the transmission pulley 44 provided integrally with the rear end portion of the rotary transmission shaft 42 is freely transmitted via the transmission belt 45. The rear support cylinder 30 is configured to be transmitted to the input pulley 46 connected to the rear end portion of the cylindrical support shaft 31 of the rear handle cylinder 30 so that the cylindrical support shaft 31 is driven. It is rotated at a higher speed than the front barrel 20 in the same rotational direction as the front barrel 20 around the same axis P1 as the rotational axis of the barrel 20. For example, the front handling cylinder 20 is rotationally driven at 507 rpm, and the rear handling cylinder 30 is rotationally driven at 700 rpm. As shown in FIG. 3, the input pulley 46 of the tube support shaft 31 is connected to the tube support shaft 31 by a screw-type connecting means 47 so as to be integrally rotatable. The connecting means 47 uses a left-hand screw so that slack due to transmission does not occur.
The output pulley 48 connected to the rear end portion of the rotary support shaft 21 of the front handle cylinder 20 so as to be integrally rotatable is to transmit the driving force of the rotary support shaft 21 to the exhaust straw transport chain 5. is there.

  Thereby, the threshing part clamps and conveys the stock side of the harvested cereal rice cake to the rear of the threshing machine body by the threshing feed chain 2, so that the tip side of the harvested cereal rice cake and the front handling cylinder 20 and the receiving net of the handling chamber 3 are received. 6, the threshing process is performed by the front handling cylinder 20 and the receiving net 6, and then the grain that is supplied to the lower side of the rear handling cylinder 30 and is crushed into the waste straw by the rear handling cylinder 30. Threshing treatment is performed so as to loosen it (so as to suppress crushing loss) and to prevent unthreshing (so as to suppress unhandled residue), and the threshing drainer from the rear handling cylinder 30 is supplied to the dust outlet 4. From outside the room.

  As shown in FIGS. 3 and 4, the rear handle cylinder 30 includes a drum plate 33 provided with a plurality of handle teeth 32 arranged in the rotational axis direction and the circumferential direction of the rear handle cylinder 30, and the front part. The cylinder support shaft 31 that is externally fitted to the rotation support shaft 21 of the handling cylinder 20 via a bearing 34 and a drum plate 33 at two locations in the direction of the rotation axis of the rear treatment cylinder 30. And a rim member 35 that connects the cylinder support shaft 31 to each other. Each rim member 35 is formed in a disc shape so as to be a lid member that closes the space between the drum plate 33 and the cylindrical support shaft 31 so as to prevent straw scraps from entering the inside of the rear handling cylinder 30. .

As shown in FIGS. 5 and 6, each rim member 35 is constituted by two split rim member 35a, the drum plate 33 are constituted by two split drum plate 33a of the semi-circular.

  Each divided rim member 35a is constituted by a semicircular plate-like body. A connecting portion 36 having a semicircular cutout 36a and a plurality of bolt holes 36b arranged around the cutout 36a is provided on the inner peripheral portion of each divided rim member 35a. A drum support portion 37 having a flange 37a and female screw members 37b located at a plurality of positions aligned in the circumferential direction of the rim member of the flange 37a is provided on the outer peripheral portion of each divided rim member 35a.

  That is, each rim member 35 includes two of the divided rim members 35a, and the cylindrical support shaft 31 is arranged around the cylindrical support shaft 31 so that the cylindrical support shaft 31 enters the notch 36a of each divided rim member 35a. The inner peripheral portion of each divided rim member 35a is connected to the flange 31a of the tube support shaft 31 by connection screws 38 that are arranged in the circumferential direction and attached to the bolt holes 36b of the connection portion 36 and the flange 31a of the tube support shaft 31. It is configured by tightening connection.

  The drum plate 33 has two divided drum plates 33a in a state where the inner surface side of each divided drum plate 33a is in contact with the flange 37a of the divided rim member 35a of each rim member 35, and the divided drum plate 33a. The parts A adjacent to each other are arranged in the circumferential direction of the rim member 35 in a state where the parts A adjacent to each other are displaced in the circumferential direction of the rear barrel 30 with respect to the parts B adjacent to each other. The divided drum plate 33a is tightened and connected to the flange 37a on the outer peripheral portion of each divided rim member 35a by a connecting screw 39 attached to the hole 33b and the female screw member 37b of the divided rim member 35a.

Accordingly, the rear handling cylinder 30 can be divided into a cylindrical support shaft 31, a plurality of rim members 35, and a single drum plate 33. Each rim member 35 of the rear handle cylinder 30 can be attached to and detached from the cylindrical support shaft 31, and is a dividing line B (see FIG. 4) 1 orthogonal to the rotational axis P1 of the rear handle cylinder 30. Thus, it can be divided into two divided rim members 35 a in the circumferential direction of the rear handling cylinder 30. The drum plate 33 of the rear handling cylinder 30 can be attached to and detached from each rim member 35, and two divided drums are formed along the dividing line A1 (see FIG. 4) in the circumferential direction of the rear handling cylinder 30. It can be divided into plates 33a.
Accordingly, when the rear handling cylinder 30 is deformed or damaged and repaired or exchanged, the rear handling cylinder 30 is changed to the front handling cylinder 20 as shown in FIG. The rear handle cylinder 30 is removed from the rotary spindle 21 while being disassembled into the cylindrical support shaft 31, the divided drum plate 33a and the divided rim member 35a, or the rear handle cylinder 30 is divided. The drum plate 33a and the divided rim member 35a can be divided and assembled to the rotary support shaft 21, and only the rear handling cylinder 30 can be detached while the front handling cylinder 20 remains attached to the threshing machine body.

Of threshing machine body 1, the upper body portion 1a supporting the front threshing drum 20 and rear threshing drum 30 with the axis around rotation transmission shaft 42, up and down relative to the lower body portion with a受網6 When the rear handling cylinder 30 is repaired or replaced, the upper body part 1a is lifted and opened to open the handling chamber 3.
The rotation transmission shaft 42 is accommodated in the pipe material 49 so that no winding of cracks or the like is generated.

[Another embodiment]
FIG. 7 shows a handling cylinder transmission structure provided with another embodiment. In this handling cylinder transmission structure, the transmission pulley 44 of the rotary transmission shaft 42 is configured as a transmission pulley using a split pulley, and this transmission pulley. By changing the belt winding diameter of 44, the rear handle 30 is driven to change speed. That is, when there are many occurrences of cut straw due to the rear handling cylinder 30, the transmission pulley 44 can reduce the speed of the rear handling cylinder 30 so that the rear handling cylinder 30 is driven at a low speed, thereby suppressing the occurrence of cutting straw.

Cross section of combine threshing machine Top view of threshing section Cross section of rear barrel attachment Longitudinal section of the rear barrel Front view of rear handling cylinder in disassembled state A perspective view of the rear handling cylinder in an exploded state Schematic of rear handle transmission structure with another embodiment Schematic showing the adjustment of the rear barrel

Explanation of symbols

3 Handling chamber 20 Front handling cylinder 21 Rotating spindle 30 of front handling cylinder Rear handling cylinder 33 Drum plate 33a Dividing drum plate 35 Rim member

Claims (1)

A threshing part structure of a threshing machine in which a front handling cylinder and a rear handling cylinder supported by a rear end portion of a rotation support shaft of the front handling cylinder are rotatably supported in a handling chamber. There,
Said rear threshing drum, and Trim member to which the is the rotation shaft fitted to rotate relative to divide freely configured and detachably drum plate to the outer peripheral portion of the rim member,
A threshing part structure of a threshing machine, wherein the drum plate is configured to be divided into a plurality of divided drum plates in the circumferential direction of the rear barrel.