JP2013118833A - Self-propelled roll baler - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a self-propelled roll baler which can prevent clogging in a feeder passage for shredded feed crops.SOLUTION: The self-propelled roll baler includes a reaping portion for reaping a feed crop; a conveying-supplying portion for cutting and conveying-supplying the feed crop reaped in the reaping portion; and a baler-forming portion for processing the cut feed crop conveyed-supplied in the conveying-supplying portion into approximately cylindrical bales, wherein in the conveying-supplying portion, a cutting member for cutting the feed crop and forcefully conveying the cut feed crop is disposed at the start portion of a conveying-supplying passage extended in the longitudinal direction; the final end portion of the conveying-supplying passage is communicated with the carrying port of the baler-forming portion; a passage direction-changing member is disposed in the rear portion of the conveying-supplying passage to diffuse and convey-supply the cut feed crop cut and forcefully conveyed with the cutting member over the whole width of the base-forming portion carrying port widened in one direction through the passage direction-changing member.

Description

  The present invention relates to a self-propelled roll baler, and more particularly, to a feeding unit that feeds (conveys and supplies) a forage crop harvested by a mowing unit to a baler forming unit.

  Conventionally, there exists what was disclosed by patent document 1 as one form of a self-propelled roll baler. That is, in Patent Document 1, a cutting part is arranged in front of the airframe that can be self-propelled, and feed crops that have been cut by the cutting part are cut into the front part of the body and fed backward (conveyance / supply). A self-propelled roll baler has been disclosed in which a feeding section is provided, and a baler forming section that uses the shredded forage crop fed from the feeding section as a bale is arranged at the rear of the machine body. In such a self-propelled roll baler, a forage crop such as green rice is harvested by a mowing unit, and the harvested forage crop is shredded by a feeding unit and fed (conveyed / supplied) to a baler forming unit. In the forming part, the shredded forage crop is made into a substantially cylindrical bale.

  The feeding unit projects a large number of chopping blades (choppers) in the radial direction (radiation direction) of the rotating shaft on the outer peripheral surface of the rotating shaft that is horizontally mounted with the axis line directed in the left-right direction. . A feed passage that communicates with the carry-in port of the baler forming portion is formed below the rotation shaft. The feed passage has a front-rear, rear-lower slope, and is gradually widened toward the rear. Is formed. Further, since the baler forming portion is formed to be widened to one side, a plurality of upper diffusion guide plates extending in the front-rear direction are provided on the inner surface forming the ceiling portion of the feed passage with a space in the left-right width direction. In addition, a plurality of lower diffusion guide plates extending in the front-rear direction are provided on the inner surface forming the bottom portion so as to protrude upward at intervals in the left-right width direction. Then, the upper and lower diffusion guide plates disperse the shredded forage crops substantially evenly in the left-right width direction, and in this state, feed it to the carry-in entrance of the baler forming section that is widened to one side. Thus, a substantially cylindrical bale that is uniform in the axial direction is formed.

JP 2002-345325 A

  However, in the above-described self-propelled roll baler, the upper and lower diffusion guide plates protruding from the ceiling and bottom of the feeding passage serve as feeding resistance, causing clogging in the feeding passage of shredded forage crops. ing.

  Then, an object of this invention is to provide the self-propelled roll baler which can prevent clogging in the supply passage of shredded forage crops.

  The self-propelled roll baler according to the invention described in claim 1 is fed by a harvesting unit that harvests the forage crop, a feeding unit that shreds and feeds the forage crop harvested by the harvesting unit, and a feeding unit. In a self-propelled roll baler comprising a baler forming section that turns a shredded forage crop into a substantially cylindrical bale, the feeding section shreds the forage crop at the start end of a feed passage extending in the front-rear direction and press-fed While the cutting body to be disposed is disposed, the carry-in entrance of the baler forming portion is communicated with the terminal portion of the feeding passage, and the passage direction changing body is disposed at the rear portion of the feeding passage, and the passage direction changing body is interposed therebetween. The chopped forage crop that has been shredded by the shredded body is spread and fed over the entire width of the inlet of the baler forming section widened to one side.

  In such a self-propelled roll baler, the passage direction changing body is disposed at the rear of the feed passage without protruding upper and lower diffusion guide plates that serve as feed resistances at the ceiling and bottom of the feed passage. The shredded forage crop that has been shredded by the shredded body and pumped can be fed by being diffused over the entire width of the carry-in entrance of the baler forming section widened to one side. Therefore, clogging in the feed passage of shredded forage crops can be prevented.

  The self-propelled roll baler according to the invention of claim 2 is the self-propelled roll baler according to the invention of claim 1, wherein the passage direction change body is formed in a plate shape and is fed to the rear portion of the feed passage. Introduced into the baler forming section widened to one side by guiding the shredded forage crops that are arranged in a slanting direction and shredded by a shredded body to one side and downward It is characterized by being fed over the entire width of the mouth.

  In such a self-propelled roll baler, the shredded forage crop is guided to one side and downward by a plate-like passage direction changing body disposed in an inclined manner with respect to the feeding direction at the rear of the feeding passage. It can be fed by being evenly diffused over the entire width of the carry-in entrance of the baler forming section widened laterally. As a result, a substantially cylindrical bale that is uniform in the axial direction is formed in the baler forming portion.

  In addition, when bale bundling work is performed by hanging a bundling net (net body) into the baler forming section, the wind generated from the shredded body does not hit the passage direction change body and directly hit the net. The bale can be firmly bound by the net.

  The self-propelled roll baler according to the invention described in claim 3 is the self-propelled roll baler according to the invention described in claim 2, wherein the passage direction changing body is capable of changing the inclined posture.

  In such a self-propelled roll baler, the full width of the carry-in entrance of the baler forming part widened to one side by shredding forage crops fed by the shredded body by appropriately changing the inclination posture of the passage direction changing body Can be distributed evenly over the whole area.

  The self-propelled roll baler according to the invention described in claim 4 is the self-propelled roll baler according to any one of claims 1 to 3, and is shredded and carried near the carry-in port of the baler forming portion. The shredded forage crops guided by the passage direction changing body are spread on the upper side of the shredded and carried body and the shredded and carried body is rotated while the shredded and carried body is rotated. Is further shredded and carried into the baler forming part through the carry-in entrance.

  In such a self-propelled roll baler, the shredded forage crop guided by the passage direction changing body is diffused on the upper side of the shredded and carried body disposed in the vicinity of the entrance of the baler forming portion. Therefore, the shredded forage crop can be further shredded while the shredded and loaded body rotates, and can be smoothly carried into the baler forming section through the carry-in entrance.

  The present invention has the following effects. That is, in the present invention, by arranging the passage direction changing body at the rear part of the feed passage, the baler forming part of the shredded forage crop that has been shredded by the shredded body and pumped to one side is provided. Since it can be distributed and fed over the entire width of the carry-in entrance, there is no need to project upper and lower diffusion guide plates that provide feed resistance at the ceiling and bottom of the feed passage, Clogging in the feed passage can be prevented.

The side view of the self-propelled roll baler concerning the present invention. Side surface explanatory drawing of a feeding part and a baler formation part. Plane explanatory drawing of a feeding part and a baler formation part. The perspective explanatory drawing of a feeding part. Side surface explanatory drawing of a feeding part. Plane explanatory drawing of a feeding part. The back surface explanatory drawing of a feeding part. The perspective explanatory drawing of a shredded body. Side surface explanatory drawing of a shredded body. Plane explanatory drawing of a shredded body. Power transmission diagram. The perspective explanatory view of the shredded body as another embodiment. Side surface explanatory drawing of the shredded body as other embodiment. Plane explanatory drawing of the shredded body as other embodiment. The perspective explanatory view of the passage direction change object as other embodiments. Explanatory drawing which consists of a top view (a), a side view (b), and a rear view (c) of a passage direction changing body as another embodiment. Side surface explanatory drawing of the channel | path direction change body as another other embodiment.

[Overall description]
Embodiments of the present invention will be described below with reference to the drawings.

  1 shown in FIG. 1 is a self-propelled roll baler according to the present embodiment. The self-propelled roll baler 1 cuts and feeds a forage crop 5 for harvesting forage crops and a forage crop harvested by the forage cutting portion 5. A feeding unit 60 and a baler forming unit 6 that turns the shredded forage crop fed by the feeding unit 60 into a substantially cylindrical bale are provided.

  That is, the self-propelled roll baler 1 has a base 3 disposed immediately above the pair of left and right crawler-type traveling units 2, 2, and a support frame 4 shown in FIG. Has been established. The support frame body 4 pivotally supports the base end portion of the cutting portion 5, and the cutting portion 5 is rotatable up and down around the pivot portion in front of the support frame body 4. A baler forming part 6 is disposed on the base 3 behind the support frame 4, and a feeding part 60 is interposed between the cutting part 5 and the baler forming part 6. A cabin-type driving unit 7 is disposed on the right front portion of the base 3, and a motor unit that is a power source shown in FIG. 11 is located immediately below a seat (not shown) provided in the driving unit 7. The engine 9 is installed. Below, each structure of the cutting part 5, the baler formation part 6, and the feeding part 60 is demonstrated in this order.

[Explanation of the cutting part]
As shown in FIG. 1, the cutting unit 5 includes a feeder house 10, a platform 11, a cutting blade body 12, a pair of left and right dividers 13 and 13, and a take-up reel 14.

  The feeder house 10 is formed in a rectangular tube shape extending in the front-rear direction, and a conveyor conveyer 15 (see FIG. 4) for conveying the harvested cereal from the front to the rear is disposed inside. The feeder house 10 is arranged on the lower left side of the operation unit 7 and a base end portion (rear end portion) is pivotally supported on the front upper portion of the support frame 4 so as to be rotatable about a horizontal axis. An elevating hydraulic cylinder (not shown) is interposed between the middle part of the lower surface of the feeder house 10 and the front end of the base 3, and the elevating hydraulic cylinder is extended and contracted so that the base end of the feeder house 10 is extended. The cutting height is adjusted by adjusting the lifting / lowering position of the cutting portion 5 at the center. As shown in FIG. 11, the conveyor 15 includes a drive shaft 17 pivoted on the base end portion (rear end portion) of the feeder house 10 with the axis line directed in the left-right direction, and the feeder house 10 with the axis line directed in the left-right direction. A conveyor belt 19 is wound around a driven drum 18 pivoted on the front end portion (front end portion).

  The platform 11 is formed in a casing shape that is substantially the same width as the left and right width of the base 3 and is open at the front, and the left side portion is connected to the front end opening portion (loading port portion) of the feeder house 10, as shown in FIG. As shown in the figure, a take-up auger 21 is laid horizontally via an auger support shaft 20 having a rotation axis oriented in the left-right direction. The scraping auger 21 scrapes the cereals harvested by the cutting blade body 12 to be described later into the platform 11 and feeds it horizontally into the front end opening (feeding port) of the feeder house 10.

  The cutting blade body 12 is formed in a clipper shape extending in the left-right direction, and is disposed in the lower part of the front end of the platform 11 over the entire width of the front end. Then, the plant base part of the planted cereal culm that is a forage crop is reaped.

  The pair of left and right dividers 13 and 13 project forward from the left and right side walls of the platform 11, respectively, and weed the forage crops planted in the field as the aircraft moves forward on the cutting and non-cutting sides. Like to do.

  The take-up reel 14 is disposed above the pair of left and right dividers 13 and 13 so as to be capable of being rotated and rotated, and the cutting-side planted culm divided by the dividers 13 and 13 is rotated to the platform 11 side. I'm trying to scratch it.

  The forage crop harvested by the cutting unit 5 is transported and supplied to a baler forming unit 6 to be described later to form a substantially cylindrical bale (not shown), and the bale is discharged out of the machine. Like to do.

[Explanation of baler forming part]
As shown in FIGS. 2 and 3, the baler forming portion 6 includes a fixed case body 33 fixed to the base 3 to form a rear opening, and a connecting body 44 at the rear upper end portion of the fixed case body 33. It is formed in a hollow box shape from an open / close case body 34 pivotally attached to form a front opening. In addition, a baler chamber 30 having a carry-in port 29 is provided inside, and in the vicinity of the carry-in port 29, the chopped forage crop is further shredded while being rotated, and the cereal straw is carried into the baler chamber 30 through the carry-in port 29. A shredded body 31 is provided. In the baler chamber 30, a baler forming body 32 for forming and processing shredded cereals that have been shredded by the cereal shredded body 31 into a bale is disposed.

  As shown in FIG. 1, the baler chamber 30 has an opening / closing cylinder 35 interposed between the ceiling portions of the fixed case body 33 and the opening / closing case body 34, and the opening / closing case body 34 centering on the pivotal portion by the opening / closing cylinder 35. Can be opened and closed.

  The baler forming body 32 is formed by arranging a large number of baler forming rollers 36 having axial lines directed in the left-right direction on the fixed case body 33 and the opening / closing case body 34 on substantially the same circumference. Each baler forming roller 36 is rotatably supported by a roller support shaft 37, and a sprocket 38 is attached to the left end portion of each roller support shaft 37.

  A large number of baler forming rollers 36 pivoted on the fixed case body 33 are wound around a fixed-side interlocking chain 39 via a sprocket 38 except for the baler forming roller 36 disposed at the top. A large number of baler forming rollers 36 pivoted on the opening / closing case body 34 and a baler forming roller 36 disposed on the uppermost portion of the fixed case body 33 are wound around an opening / closing side interlocking chain 40 via a sprocket 38. The baler forming roller 36 disposed at the uppermost part and the baler forming roller 36 disposed at the foremost part are respectively wound around a roller transmission chain 42 via an input sprocket 41 to form a part of a baler forming body transmission mechanism 43 described later. doing. 45 is a guide sprocket.

  The forage crops fed into the baler chamber 30 are wound while being rotated by a large number of baler forming rollers 36 rotated (rotated) in the same direction, gradually increasing the diameter of the column, and having a predetermined size. A veil is formed. When the bale reaches a predetermined size, a synthetic resin net (net-like body) 47 is fed out from a bundling device 46 (see FIG. 1) placed on the ceiling of the fixed case body 33, and the net 47 is a peripheral surface of the bale. Wound and tied together. Thereafter, the opening / closing case body 34 is opened to release the bound bale to the outside of the machine.

  The cereal chopped body 31 is arranged so that the chopping and carrying-in blade 50 which is a rotary blade and the fixed blade 51 face each other, and both cooperate to chop the forage crop. A plurality of shredding and carrying-in blades 50 are supported on a rotating support shaft 52 that is horizontally mounted with its axis line directed in the left-right direction. The fixed blade 51 has its tip portion disposed between the shredding and loading blades 50 and 50 adjacent to each other. A shredder input sprocket 54 is attached to the right end portion of the rotary support shaft 52 to form a part of a shredder transmission mechanism 55 described later. In FIG. 2, 56 is a scraper for preventing the grain crops 31 from being clogged with forage crops.

[Description of feeding section]
As shown in FIG. 2, the feeding unit 60 is interposed between the cutting unit 5 and the baler forming unit 6 to communicate with each other as described above. That is, there is a side surface between the carry-out port 59 (see FIG. 4) formed at the base end (rear end) of the feeder house 10 and the carry-in port 29 of the baler chamber 30 provided in the baler forming unit 6. A feeding passage forming body 61 having a feeding passage 62 bent in the shape of a letter “he” is interposed, and the feeding passage 62 in the feeding passage forming body 61 is connected to the carry-out / inlet 59, 29. Communicate.

  As shown in FIG. 3, the baler forming portion 6 is formed to be widened to one side (right side in the present embodiment), and is formed to be wider (substantially twice) in the left-right direction than the feeder house 10. . Therefore, the starting end portion (upstream side portion) of the feed passage 62 is formed to be slightly wider than the left and right width of the feeder house 10 and communicates with the carry-out port 59 of the feeder house 10. And the middle part of the feed passage 62 located behind the support frame 4 is formed so that the left and right widths are gradually widened toward the downstream side. Further, the terminal end portion (downstream side portion) of the feeding passage 62 has a width substantially the same as the left and right width of the baler forming portion 6 and communicates with the carry-in entrance 29 of the baler forming portion 6.

  The feeding unit 60 is provided with a shredded body 63 that shreds and feeds feed crops at the start end of a feeding passage 62 extending in the front-rear direction, while the baler forming unit 6 is disposed at the end of the feeding passage 62. The carry-in entrance 29 is communicated.

  As shown in FIGS. 4 to 7, a chopped body 63 is disposed in the upstream portion (front portion) of the feed passage 62. That is, the shredded body 63 projects a large number of support pieces 65 formed in a flat cylindrical shape on the outer peripheral surface of the rotating shaft 64 whose axis is placed in a direction orthogonal to the feeding direction of the shredded forage crop. doing. As shown in FIGS. 8 to 10, a base end portion 66 c of a shredder blade 66 formed in a plate shape extending in the radial direction (radial direction) is detachably inserted into each support piece 65. 66 is detachably attached in a protruding shape. Tapered cutting surfaces 66a and 66b are formed on one side of the chopping blade 66 formed in a plate shape on the rotating side and the opposite side, respectively. A belt-like pressure feed blade 67 is brought into contact with and supported by the support piece 65 protruding from the outer peripheral surface of the rotary shaft 64. In this embodiment, the support piece 65 is thin between the support pieces 65 and 65 adjacent to each other in the axial direction of the rotary shaft 64. A belt-like pressure feeding blade 67 extending in the axial direction of the rotating shaft 64 is horizontally mounted on the rotating side of the cutting blade 66.

  A plurality of receiving blades 68 are arranged in a fixed state at intervals in the left-right direction (the axial direction of the rotating shaft 64) at the bottom of the feed passage forming body 61 located below the rotating shaft 64. The blade 68 and the tip of each chopping blade 66 projecting from the rotating shaft 64 via the support piece 65 cooperate to chop the forage crop. The receiving blade 68 is detachably attached to the bottom of the feed passage forming body 61 so that it can be easily replaced as needed depending on the type of feed crop to be cut or maintenance.

  A scraping body 69 is disposed on the downstream side of the shredded body 63 in the feed passage 62. In other words, the scraping body 69 is disposed so as to extend in parallel with the rotary shaft 64 at a position above the rotational shaft 64 of the shredder 63 and in the vicinity of the rotational locus of the tip of the shredder blade 66 from below. The forage crop carried around by the tip of the adjacent shredding blade 66 is scraped off.

  The scraping body 69 is disposed in close proximity along the rotational trajectory of the tip of the shredded blade 66 to form a concave arcuate surface, and toward the rear upper side from the lower end edge of the front surface portion 69a. A lower surface portion 69b that has been flattened to form a flat front low rear high inclined surface, and a scraping portion 69c that has an inner angle of a connection edge between the lower surface portion 69b and the front surface portion 69a of 90 degrees or less. .

  A guide body 57 is provided on the side wall of the feed passage forming body 61 located on the opposite side to the widening direction of the baler forming portion 6 widened to one side (right side in the present embodiment), that is, the left side wall portion 114. The scraper 69 is disposed below the left side of the scraper 69. The guide body 57 attaches the front end edge portion 57b of the plate-shaped guide main body 57a to the left side wall portion 114 of the supply passage forming body 61, while the rear end edge portion 57c of the guide main body 57a is attached to the left side of the supply passage formation body 61. The bait forming part is a cut feed crop that is arranged away from the wall part 114 in the widening direction of the baler forming part 6 and fed along the surface of the guide main body 57a that is inclined in the plan view of FIG. It is made to carry in over the full width of the six carry-in entrances 29.

  A passage direction changing body 58 is disposed at the rear portion of the feeding passage 62, and the shredded forage crop that has been shredded by the shredded body 63 through the passage direction changing body 58 is widened to one side. The entire width of the carry-in port 29 of the formed baler forming unit 6 is diffused and fed.

  That is, the passage direction changing body 58 is formed in a plate shape, and is disposed at the rear portion of the feeding passage forming body 61 so as to be inclined with respect to the feeding direction (the front-rear direction in the present embodiment). The shredded forage crop shredded by 63 is guided to one side (right side in the present embodiment) and downward, over the entire width of the carry-in entrance 29 of the baler forming section 6 widened to one side. It is distributed and sent.

  The shredded forage crop guided by the passage direction changing body 58 is diffused on the upper side of the shredding and loading blade 50 disposed in the vicinity of the carry-in entrance 29 of the baler forming section 6. The shredding and carrying-in blade 50 is configured to further shred the shredded forage crop while rotating and carry it into the baler forming part 6 through the carry-in entrance 29.

  The self-propelled roll baler configured as described above has the following operational effects. That is, the feed crops cut by the cutting unit 5 are shredded by rotating a large number of shredder blades 66 protruding from the outer peripheral surface of the rotary shaft 64 around the rotary shaft 64, and shredded feed. The crop can be fed to the baler forming unit 6. At this time, a scraping body 69 extending in parallel with the rotation shaft 64 is disposed at a position behind the rotation shaft 64 of the chopping body 63 and in the vicinity of the rotation locus of the tip of the chopping blade 66. The shredded forage crop that the tip of the shredding blade 66 adjacent from below is carried around is scraped firmly by the scraping body 69. As a result, the tip of the shredded blade 66 carries the shredded forage crop, causing clogging of the forage crop between the shredded blade 66 and the peripheral wall, and the shredded blade 66 for shredding the forage crop. No loss of efficiency.

  Since the scraping portion of the scraping body 69 is formed in an acute angle with an inner angle of the connecting edge between the front surface portion and the lower surface portion being 90 degrees or less, the tip portion of the shredder blade 66 that is adjacent from below is formed. The forage crops that are carried around are steadily scraped off by the scraper. At this time, the front surface portion is formed as a concave circular arc surface arranged in close proximity along the rotation trajectory of the tip of the chopping blade 66, so that the gap between the tip of the rotating chopping blade 66 and the front surface portion is made as small as possible. Therefore, the shredded forage crop that the tip of the shredder blade 66 carries around is easily scraped off by the scraping portion located at the start end of the gap. Since the lower surface portion extends from the lower end edge of the front surface portion to the rear upper side to form a flat front low rear high inclined surface, the start end portion of the feeding passage 62 communicating with the rear side of the scraping body 69 is wide-angled. The shredded forage crop scraped off by the scraping part can be smoothly fed to the baler forming part 6 along the lower surface part. That is, almost all the shredded forage crops including the shredded forage crops scraped off by the scraping-off unit are smoothly fed to the baler forming unit 6 without staying in the feed passage 62.

  Since the cut feed crop conveyed / supplied along the surface of the guide body 57a having the inclined surface is carried over the entire width of the carry-in port 29 of the baler forming unit 6, the shredded feed crop is carried into the carry-in port 29. Can be evenly diffused and fed to the baler forming section 6. As a result, a substantially cylindrical bale that is uniform in the axial direction is formed in the baler forming portion 6.

  The shredder blade 66 of the shredded body 63 shreds the forage crop, and the shredded forage crop is fed by the belt-like pumping blade 67 for feeding. That is, the shredded body 63 can have a sufficient shredding power of the feed crop and a sufficient feeding power of the shredded feed crop. Therefore, the shredded body 63 has a simple structure, has a shredding function and a feeding function, chops the feed crop steadily, and feeds the chopped feed crop steadily without retaining it. Can do.

  The chopping blade 66 can be attached to the support piece 65 protruding from the outer peripheral surface of the rotating shaft 64 by replacing the cutting surface of the chopping blade 66 between the rotating side and the opposite side. It can be done easily. Then, the pressure-feeding blade 67 can be easily and reliably attached by causing the belt-shaped pressure-feeding blade 67 to abut on and support the support piece 65 protruding from the outer peripheral surface of the rotating shaft 64. In the present embodiment, the pressure-feeding blade 67 can be firmly supported by horizontally placing the belt-shaped pressure-feeding blade 67 between the support pieces 65 adjacent to each other in the axial direction of the rotation shaft 64.

  Each receiving blade 68 and the tip of each chopping blade 66 projecting from the rotary shaft 64 cooperate to chop the feed crop, so that the feed crop can be chopped firmly. . As a result, the bale molding efficiency can be improved.

  By disposing the passage direction changing body 58 at the rear of the feeding passage 62 without protruding upper and lower diffusion guide plates serving as feeding resistances at the ceiling and bottom of the feeding passage 62, the shredded body The shredded forage crop that has been shredded by 63 and pumped can be fed by being diffused over the entire width of the carry-in port 29 of the baler forming section 6 widened to the right. Therefore, clogging in the feed passage 62 for shredded forage crops can be prevented.

  A baler which is widened to the right side by guiding a shredded forage crop to the right and downward by a plate-like passage direction changing body 58 which is disposed at a rear portion of the feeding passage 62 in an inclined manner with respect to the feeding direction. It can be fed by being evenly diffused over the entire width of the carry-in port 29 of the forming unit 6. As a result, a substantially cylindrical bale that is uniform in the axial direction is formed in the baler forming portion 6. When bundling work is performed by hanging a bundling net (net body) 47 wound in a roll shape into the baler forming portion 6, wind generated from the shredded body 63 is generated in the direction of the passage. Since it does not directly hit the net 47 when hitting the modified body, bale binding by the net 47 can be performed firmly.

  The shredded forage crops guided by the passage direction changing body 58 are diffused on the upper side of the shredding and loading blade 50 disposed in the vicinity of the carry-in entrance 29 of the baler forming section 6. The shredded forage crop can be further shredded while the cutting and carrying-in blade 50 is rotated, and can be smoothly carried into the baler forming section 6 through the carry-in entrance 29.

  The configuration of the feeding unit 60 will be described more specifically. That is, as shown in FIGS. 4 to 7, the supply passage forming body 61 includes an upstream supply passage forming body 110 disposed in the upper half of the support frame body 4 and a downstream disposed on the downstream side thereof. The side feed passage forming body 111 is formed.

  The upstream side supply passage forming body 110 has a front wall portion 113 having an opening 112 aligned with the carry-out port 59 of the feeder house 10 attached to the front surface of the support frame body 4, and left and right sides on the left and right side surfaces of the support frame body 4. The wall portions 114 and 115 are attached, the ceiling wall portion 116 is detachably attached to the ceiling surface of the support frame body 4, and the bottom surface portion 117 is stretched on the middle portion surface of the support frame body 4 so as to be inclined in front and rear and low. Formed.

  A chopped body 63 is placed between the left and right side wall portions 114 and 115 so as to rotate in the X direction shown in FIG. Z is the feed flow direction of the feed crop. On the ceiling wall portion 116 located on the downstream side of the shredded body 63, a scraping body 69 having the same left and right width as the interval between the left and right wall portions 114 and 115 is disposed so as to bulge downward. The scraping body 69 includes a front surface portion 69a, a lower surface portion 69b, a scraping portion 69c, and left and right side surface portions 69d and 69d. The front surface portion 69a is formed on a concave arcuate surface and is arranged close to the rotation locus of the tip of the chopping blade 66. The lower surface portion 69b is formed on a flat front low / high rear inclined surface and extends from the lower end edge of the front surface 69a toward the rear upper side. The scraping portion 69c has an inner angle of a connection edge portion between the lower surface portion 69b and the front surface portion 69a of 90 degrees or less, and at a rear upper position of the rotating shaft 64 of the shredded body 63 in the right side view of FIG. It is formed in a V shape. That is, the scraping portion 69c is formed as a downward-pointed streak extending in the left-right direction. The left and right side surfaces 69d and 69d form the left and right side surfaces of the scraping body 69, and face the left and right side walls 114 and 115 in a proximity state.

  In the front half portion of the bottom surface portion 117 that is inclined in an inclined manner, a horizontally long rectangular receiving blade protruding opening 123 that extends in the left-right direction is opened at a position directly below the rotating shaft 64 of the shredded body 63 to receive the receiving portion. A plurality (11 in this embodiment) of receiving blade holders 124 are vertically arranged in the blade protruding opening 123 so as to be aligned in the left-right direction. Each receiving blade holder 124 has an upper surface opening shape, and communicates with the receiving blade protruding opening 123. Each receiving blade holder 124 is attached with a lower end portion of the receiving blade 68 so that it can be inserted and removed in a rearward tilted state, and each receiving blade 68 protrudes upward from the receiving blade protruding opening 123 in a rearward inclined state. Therefore, each receiving blade 68 is in a state of protruding upward from the bottom surface portion 117 with a certain interval in the left-right direction in the rear view of FIG. A substantially horizontal surface portion 118 is stretched over the latter half of the bottom surface portion 117, that is, at a position below the scraping body 69.

  A guide body 57 is attached to the left side wall 114, and the guide main body 57a of the guide body 57 has an upper end edge along the lower surface portion 69b of the scraping body 69, and has an inclined shape with front, rear, and rear heights, The scraper 69 is disposed close to the lower surface 69b. The guide main body 57 a of the guide body 57 has a lower end edge portion that is substantially horizontal along the substantially horizontal plane portion 118, and is disposed close to the substantially horizontal plane portion 118.

  The downstream side supply passage formation body 111 includes a left side wall portion 125 extending rearward from the left side wall portion 114 of the upstream side supply passage formation body 110 and a rear portion of the right side wall portion 115 of the upstream side supply passage formation body 110. An inclined wall portion 126 extending obliquely outward from the rear side, a right wall portion 127 extending in parallel with the left wall portion 125 rearward from the rear edge of the inclined wall portion 126, and the support frame 4 A support surface portion 128 extending downwardly and downwardly from the rear end edge portion, a passage direction changing body 58 continuously extending downwardly downwardly from the rear end edge portion of the support surface portion 128, and a substantially horizontal surface portion 118. A downwardly inclined lower surface portion 129 extending downwardly downward from the rear edge of the rear edge and an arcuate lower surface portion 130 extending circularly upward and downwardly from the downwardly inclined lower surface portion 129 are formed. The shredding and carrying-in blade 50 is disposed in a concave space 131 formed by the downward inclined lower surface portion 129 and the arc-shaped lower surface portion 130 and extending in the left-right direction. Y is the rotational direction of the shredding and loading blade 50. The left and right side wall portions 125 and 127 are also formed as the left and right side wall portions of the baler forming portion 6.

  The passage direction changing body 58 includes a change main body 58a formed in a horizontally-long rectangular plate shape, a rear change piece 58b formed extending rearward and downward from a rear end edge of the change main body 58a, and a left edge of the change main body 58a. Left connection piece 58c projecting upward along the right part, right connection piece 58d projecting upward along the right edge part of the change main body 58a, and the upper surface front end edge part of the change main body 58a. The reinforcing member 58e extends in the left-right direction. The change main body 58a is inclined downward to the rear and inclined to the upper right after lower left and right, and the left connecting piece 58c is brought into contact with the left wall portion 125 and the front and rear ends of the left connecting piece 58c are connected. The right connection piece 58d is brought into surface contact with the right side wall 127, and the front and rear ends of the right connection piece 58d are connected by a connection bolt 133.

  In this way, the shredded forage crop that has been shredded by the shredded body 63 and pumped is formed along the lower surface 69b of the scraping body 69 in the rear upper direction in a wide-angled manner. On the upstream side, the feed port 29 of the baler forming section 6 is fed to the rear upper side and guided to the change main body 58a and the rear change piece 58b disposed in an inclined manner and widened to the right side. The chopping and loading blade 50 is spread and fed over the entire width. At this time, the shredded forage crop carried by the tip of the shredder blade 66 of the shredder 63 is scraped off by the scraper 69c of the scraper 69, and is fed to the downstream change main body 58a. I have to.

  As shown in FIGS. 8 to 10, the shredded body 63 is spaced apart in a line on the same straight line in the axial direction on the outer peripheral surface of the rotating shaft 64 formed in a drum shape extending in the left-right direction with its axis line extending. A plurality of (three in this embodiment) support pieces 65 are provided in the radial direction (radiation direction). A plurality of (three in the present embodiment) support pieces 65 are projected in the radial direction (radiation direction) in four rows displaced 90 degrees each in the circumferential direction of the rotation shaft 64. Moreover, each support piece 65 is arranged one by one on the same plane orthogonal to the rotation shaft 64. A pair of support shafts 120 and 120 are coaxially provided at both left and right ends of the rotation shaft 64, and the support shafts 120 and 120 are pivotally supported on the left and right wall portions 114 and 115 via the shaft support members 121 and 121. doing. 122 is a donut plate-like box attached to the base end of the outer peripheral surface of the support shaft 120, and the forage crop is entangled with the support shaft 120 by forming the radius of the box 122 larger than the radius of the rotating shaft 64. Is preventing.

  The support piece 65 is formed of a flat rectangular and cylindrical support main piece 65a and a continuous piece 65b protruding from the support main piece 65a. And the base end part of the support main piece 65a and the connection piece 65b is connected with the rotating shaft 64 continuously. A base end portion 66c of the chopping blade 66 is detachably attached to the support main piece 65a, and an insertion connecting bolt 134 is inserted through the support main piece 65a and the base end portion 66c of the chopping blade 66 in a transverse penetrating manner. A nut 135 is fastened and fixed to the tip of the insertion connecting bolt 134.

  Pressure feed blades 67 are attached to the rotation side of the three support pieces 65 arranged in a line in the axial direction of the rotation shaft 64, and a total of four pressure feed blades 67 are attached to the four rows of support pieces 65, respectively. The pressure feeding blade 67 has the same width as the protruding width of the support main piece 65a and extends in a strip shape in the left-right direction so as to have the same length as the rotation shaft 64, and from the tip edge of the blade body 67a to the rotation side. It is formed from a front end edge bent piece 67b extending in a bent shape. The blade body 67a is provided in a standing manner between the outer peripheral surface of the rotating shaft 64 and the rotating side surface of the support piece 65. The leading edge bent piece 67b stands along the rotating side surface of the support piece 65 to a position near the lower end of the cut surface 66a. The pressure feeding blade 67 may be formed in a flat belt shape and erected from the rotating shaft 64 to a position in the vicinity of the lower end of the cutting surface 66a, so that it can be continuously provided in a superposed state on the rotating side surface of the support piece 65.

  The twelve chopping blades 66 attached to each support piece 65 are arranged so as to pass one by one between eleven receiving blades 68 arranged at intervals in the left-right width direction. And three shredded blades 66 that rotate feed crops that are horizontally suspended between the receiving blades 68 adjacent to each other in the left-right direction in a line in the X direction in a side view of FIG. The parts are shredded at the same time.

  A large number of shredding and carrying-in blades 50 are provided on the rotation support shaft 52 and are arranged close to each other in the left-right direction. That is, the horizontal spacing of the shredding and loading blade 50 is set to be smaller than the horizontal spacing of the shredded blade 66, and the shredded forage crops shredded by the shredded blade 66 are further shredded. It is carried into the baler forming body 32.

  The dead space on the base 3 located directly below the shredded body 63 is a transmission case arrangement space S as shown in FIG. A transmission case (counter case) 70 is arranged in the transmission case arrangement space S. As shown in FIG. 11, the transmission case 70 has first to fourth transmission shafts 72, 73, 74, and 75 that are axially directed in the left and right directions on a case body 71 that is formed in a flat box shape with a narrow left and right width. Are laid horizontally in parallel with a gap in the front-rear direction.

[Description of power transmission mechanism]
Hereinafter, the power transmission mechanism of the self-propelled roll baler 1 will be described in detail with reference to FIG. That is, in the case main body 71, the self-propelled roll baler 1 has a first transmission gear 76 attached to the first transmission shaft 72 and a second transmission gear 77 meshed with the first transmission gear 76 attached to the second transmission shaft 73. A third transmission gear 78 that meshes with the second transmission gear 77 is attached to the third transmission shaft 74. A fourth transmission gear 79 is attached to the third transmission shaft 74, and a fifth transmission gear 82 that meshes with the fourth transmission gear 79 is attached to the fourth transmission shaft 75.

  The first transmission shaft 72 protrudes from the case main body 71 to the right side and extends to the right side, and a working portion input pulley 83 is attached to the right end portion. The engine 9 has an output shaft 84 projecting to the left side, a first output pulley 85 is attached to the output shaft 84, and a working unit transmission belt 86 is interposed between the first output pulley 85 and the working unit input pulley 83. Winding. 87 is a transmission unit, 88 is a transmission unit input shaft, 89 is a transmission unit input pulley, 90 is a second output pulley, 91 is a transmission unit transmission belt, 92 is a drive shaft provided in the transmission unit 87, and 98 is a traveling unit 2. It is a drive wheel and is attached to both ends of the drive shaft 92.

  The support shaft 120 of the chopped body 63 is disposed immediately above the first transmission shaft 72, and the chopped body input pulley 138 attached to the right end of the support shaft 120 and the first transmission outside the case body 71. A chopped body transmission belt 95 is wound between the right output pulley 94 attached to the middle portion of the shaft 72 to form a chopped body transmission mechanism 139.

  The third transmission shaft 74 protrudes from the case main body 71 to the right side, and a grain shredded body output sprocket 96 is attached to the right end portion. Between the grain chopped body input sprocket 54 and the grain chopped body output sprocket 96 attached to the right end of the rotary spindle 52 of the grain chopped body 31, first and second intermediate sprockets 98 a, The grain chopped body transmission chains 97a and 97b are wound through 98b to form the grain chopped body transmission mechanism 55. That is, the cereal shredded body transmission mechanism 55 is disposed on one side of the baler forming portion 6 (on the right side in the present embodiment) and interlocked with the cereal shredded body 31. 99 is an intermediate shaft.

  The fourth transmission shaft 75 protrudes leftward from the case main body 71, and a left output sprocket 93 is attached to the left end. A roller transmission chain 42 is wound around the left output sprocket 93 and the input sprocket 41 disposed at the top of the baler forming body 32 and the input sprocket 41 disposed at the foremost part to form a baler forming body transmission mechanism 43. That is, the baler forming body transmission mechanism 43 is disposed on the transmission case 70 on the left and right other sides (the left side in the present embodiment) of the baler forming portion 6 and interlocked with the baler forming body 32.

  A cutting portion side output gear 140 is attached to the fourth transmission shaft 75, while a cutting portion side input gear 142 is attached to the intermediate transmission shaft 141 projecting leftward from the left wall portion 114 of the feed passage forming body 61. Thus, the cutting portion side input gear 142 is engaged with the cutting portion side output gear 140. A conveyance conveyor transmission mechanism 100 is interposed between the intermediate transmission shaft 141 and the drive shaft 17 of the conveyance conveyor 15 extended to the left side. Reference numeral 101 denotes a cutting main shaft, 102 denotes a main shaft transmission mechanism, 103 denotes an auger transmission mechanism, 104 denotes a cutting blade body operating shaft, 105 denotes a cutting blade body transmission mechanism, 106 denotes a take-up reel support shaft, and 107 denotes a reel transmission mechanism.

  In the self-propelled roll baler 1 configured as described above, the cereal chopped body transmission mechanism 55 linked to the cereal chopped body 31 is arranged on the right side of the baler forming portion 6, while being interlocked with the baler forming body 32. The connected baler forming body transmission mechanism 43 is disposed on the left side of the baler forming portion 6, and the cereal shredded body transmission mechanism 55 and the baler forming body transmission mechanism 43 are linked and connected to a transmission case 70 linked to the engine 9. Therefore, it is possible to avoid the left side portion of the airframe from being biased and becoming heavy. That is, since the transmission mechanism on the downstream side from the transmission case 70 is distributed to the left and right, the weight of the airframe can be reduced.

  Moreover, since the cereal chopped body transmission mechanism 55 does not need to maintain the corresponding strength (particularly, tensile strength) at the same time as that of the baler forming body transmission mechanism 43, the cereal chopped body transmission mechanism 55 does not change. Can be reduced in weight.

  Furthermore, the transmission case 70 can be disposed by effectively utilizing the dead space on the base 3 located directly below the shredded body 63. In other words, the dead space formed below the feeding passage 62 formed in an upwardly inclined manner on the rear upper side is effectively used as the transmission case arrangement space S, so that the left and right parts are distributed to the engine 9 via the transmission case 70. The cereal chopped body transmission mechanism 55 and the baler forming body transmission mechanism 43 can be firmly linked together.

  Further, the transmission case 70 can appropriately shift the grain chopped body 31 through the grain switching body transmission mechanism 55 by the shift switching mechanism 80. That is, the cutting operation can be efficiently performed by shifting the rotational speed of the rotary blade 50 to the high speed stage or the low speed stage according to the type of forage crop to be shredded by the cereal shredded body 31. The bale molding work efficiency can be increased.

[Other Embodiments of Shredded Body]
12 to 14 show a chopped body 63 according to another embodiment, and the pressure-feeding blade 670 of the chopped body 63 extends in the right direction which is the rotational direction of the rotary shaft 64 and the axial direction of the rotary shaft 64. The pumping surface 671 is curved so that the pumping force is generated in the resultant force direction, and the shredded forage crop is pumped over the entire width of the baler forming part 6 widened to one side (right side in this embodiment). It is configured to do.

  The pressure feeding blade 670 extends in the left-right direction and is formed in a band shape that is the same width as the left-right width of the rotation shaft 64 and slightly wider than the protruding width of the support piece 65, and the left side portion on the outer peripheral surface of the rotation shaft 64 is formed. Arranged on the rotation side and twisted to the rotation side, and arranged on the outer peripheral surface of the rotation shaft 64 on the right side portion on the counter-rotation side and twisted on the counter-rotation side, a pumping force is generated in the resultant direction in the right direction. Thus, a twisted surface is formed on the pressure feeding surface 671.

  Further, the three support pieces 65 arranged at intervals in the axial direction of the rotation shaft 64 are arranged such that the left support piece 65 is arranged on the rotation side with respect to the center support piece 65 and the right support piece 65 is arranged in the center. The support piece 65 is arranged on the counter-rotation side, and is arranged obliquely intersecting the axis of the rotation shaft 64. The pressure feed blades 670 are arranged along the rotation side of the row of the four support pieces 65 arranged in this way, and the pressure feed blades 670 are connected to and supported by the support pieces 65.

  Such a self-propelled roll baler is formed on one side by a pumping blade 670 formed by curving the pumping surface 671 so that a pumping force is generated in the resultant direction of the rotational axis 64 and the axial direction of the rotary shaft 64. Since the entire width of the carry-in entrance 29 of the widened baler forming part 6 can be uniformly diffused and fed, the baler forming part 6 forms a substantially cylindrical bale that is uniform in the axial direction. can do.

[Other Embodiments of Passage Direction Changing Body]
15 and 16 show a passage direction changing body 580 as another embodiment, and this passage direction changing body 580 has a change main body 581 formed in a horizontally long rectangular plate shape arranged in a slanted shape with a front height and a low height. At the same time, a diagonal line connecting the left front end and the right rear end is defined as a partition line 584 between the left side 582 and the right side 583, and the left side 582 is an inclined surface having a left lower rear height. 585 is a front edge reinforcing portion formed by folding the front end edge of the modified main body 581 upward, 586 is a rear edge reinforcing portion formed by folding the rear end edge of the modified main body 481 upward, and 587 is the left side surface portion 582. A left-side connection body 588 formed from a right-hand side edge portion and formed in a right triangle plate shape, 588 is a right-side connection body formed from a right-side edge portion of the right-side surface portion 583 and extends in the front-rear direction, and 589 is left and right-hand side It is a connecting hole for connecting the passage direction changing body 580 to the left and right side wall portions 114, 115 formed at the front and rear portions of the connecting bodies 587, 588.

  Constructed in this manner, the shredded forage crop fed by the shredded body 63 is carried into the baler forming section 6 widened to one side by the right side face part 583 which is a left low rear high inclined surface. It is configured to be able to feed evenly spread over the entire width of the mouth 29.

[Another embodiment of the passage direction changing body]
FIG. 17 shows a passage direction changing body 150 as another embodiment, and this passage direction changing body 150 is capable of changing the inclined posture. That is, the passage direction changing body 150 has the same basic structure as the passage direction changing body 58, but the left and right pivot pins 151, 151 at the front end edge portion are arranged horizontally in the left-right direction. Then, the configuration differs in that the rear end edge portion can be adjusted up and down with the left and right pivot pins 151 and 151 as the center, and the inclination direction of the passage direction changing body 150 can be changed. . Reference numeral 152 denotes an arc-shaped left inclined posture changing long hole centered on the left and right pivot pins 151, 151. The left inclined posture changing long hole 152 is formed in the left wall 114. 153 is a change body, 154 is a left connection piece projecting upward along the left edge of the change body 153, 155 is an adjustment pin protruding outward from the rear end of the left connection piece 154, An adjustment pin 155 is inserted through the left inclined posture changing long hole 152. Reference numeral 156 denotes an arc-shaped right inclination posture changing long hole centered on the left and right pivot pins 151, 151. The right inclination posture changing long hole 156 is formed in the left wall 115. 157 is a right connecting piece projecting upward along the right edge of the change main body 153, 158 is an adjustment pin protruding outward from the rear end of the right connecting piece 157 to change the right inclination posture. An adjustment pin 158 is inserted through the long hole 156. Reference numeral 159 denotes a hanging piece that is suspended from the right front end edge of the change main body 153 and supports the right pivot pin 151. They are arranged on the same horizontal axis.

  With this configuration, the left side wall 114 is adjusted by swinging the rear end edge of the passage direction changing body 150 in the vertical direction around the same axis of the left and right pivot pins 151 and 151 that are horizontal in the horizontal direction. By tightening and fixing the adjustment pins 155 and 158, the inclination posture of the passage direction changing body 150 can be changed. Then, the shredded forage crop fed by the shredded body 63 is changed by appropriately changing the inclination posture of the passage direction changing body 150 according to the type of shredded forage crop fed by the shredded body 63 and the like. Further, it is possible to uniformly feed the entire width of the carry-in entrance 29 of the baler forming section 6 widened to one side (right side in the present embodiment).

DESCRIPTION OF SYMBOLS 1 Self-propelled roll baler 2 Traveling part 3 Base 4 Support frame 5 Cutting part 6 Baler formation part 31 Grain shredded body 32 Baler formation body 43 Bale formation body transmission mechanism 55 Shredded body transmission mechanism

Claims (4)

A cutting part for cutting forage crops, a feeding part for cutting and feeding the forage crops harvested by the cutting part, and a baler forming the shredded forage crops fed by the feeding part into a substantially cylindrical bale In a self-propelled roll baler comprising
The feed section is provided with a shredded body for shredding and pressure-feeding feed crops at the start end of the feed passage extending in the front-rear direction, while communicating with the carry-in port of the baler forming section at the end of the feed passage. Let
A passage direction change body is disposed at the rear part of the feed passage, and a baler is formed through the passage direction change body so that the shredded forage crop chopped by the shredded body is widened to one side. A self-propelled roll baler characterized in that it is fed while being diffused over the entire width of the carry-in port of the section.   The passage direction change body is formed in a plate shape and is disposed at an inclination with respect to the feeding direction at the rear part of the feeding passage, and one side of the shredded forage crop that is shredded by the shredded body and pumped 2. The self-propelled roll baler according to claim 1, wherein the self-propelled roll baler is guided by being directed downward and diffused over the entire width of the carry-in entrance of the baler forming portion widened to one side.   The self-propelled roll baler according to claim 2, wherein the passage direction changing body is capable of changing an inclined posture. While arranging the shredded and carried body in the vicinity of the carry-in entrance of the baler forming part, the shredded forage crop guided by the passage direction changing body is diffused on the upper side on the shredded and carried body,
The shredded and transported body is configured to further shred the shredded forage crop while rotating and transport the shredded forage crop through the entrance to the baler forming section. Self-propelled roll baler.

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