JP2015223131A - Combine harvester - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a combine harvester for preventing an auxiliary cutting blade device from being broken or the like, by enabling an auxiliary cutting device to retract backward by buffer means, when it receives a pressing force from the front, and the retrieving action of the auxiliary cutting device.SOLUTION: To the machine frame of a running machine, there are hinged the base end parts of transversely paired support arms extending forward and downward through the arm spindles having axes directed transversely, thereby to support an auxiliary cutting blade device between the leading end parts of the two support arms. The auxiliary cutting blade device is supported through a connecting/releasing mechanism on a cutting part so that it is held at a predetermined ground height and can be retracted backward when it receives a pressing force from the front. At the back of each support arm, there is arranged cushioning means for cushioning the backward saving action of each support arm.

Description

  The present invention relates to a combine, and more particularly, to a combine in which a retracting operation of an auxiliary cutting blade device that can be retracted is buffered by a buffering means.

  Conventionally, there is one disclosed in Patent Document 1 as one form of a combine. That is, in Patent Document 1, the traveling machine body is provided with a cutting part having a main cutting blade device that cuts off the tip part of the raised hair, while the traveling machine body is provided with a cutting edge part of which the tip part is cut by the main cutting blade apparatus. A combine provided with an auxiliary cutting blade device that cuts the residue is disclosed. And this combine lays the arm support shaft which turned the axis line in the left-right direction on the body frame of the traveling machine body, and extends toward the front and lower sides respectively on the left and right side end portions and the middle portion of the arm support shaft. Supporting the base end of the three support arms, an auxiliary cutting blade device is installed between the tip ends of these three support arms, and the intermediate arm is attached to the receiver projecting forward and downward from the machine frame. The urging means is arranged in a standing manner toward the front upper side toward the back of the support shaft, and the auxiliary cutting blade device is elastically urged to the upward side via the arm support shaft in the middle by this urging means. Thus, it is elastically supported at a predetermined ground height.

JP 2010-227019 A

  However, the biasing means is configured such that although the auxiliary cutting blade device can be sufficiently retracted in the downward direction, the auxiliary cutting blade device cannot be sufficiently retracted in the backward direction. When the pressure is applied, the auxiliary cutting blade device may be damaged.

  Therefore, the present invention enables the auxiliary cutting blade device to be retracted backward when the auxiliary cutting blade device receives a pressing force from the front, and allows the retracting operation of the auxiliary cutting blade device to be buffered by the buffer means. An object of the present invention is to provide a combine that can prevent the auxiliary cutting blade device from being damaged.

The invention described in claim 1
While the traveling machine body is provided with a cutting part having a main cutting blade device that cuts the tip part of the raised hair,
In the traveling machine body, a combine provided with a sub cutting blade device that cuts the residue of the napped hairs whose head portion has been cut by the main cutting blade device,
A base frame of a pair of left and right support arms extending forward and downward is pivotally supported on the machine frame of the traveling machine body via an arm support shaft having an axis line in the left-right direction between the front ends of both support arms. A secondary cutting blade device was installed,
The auxiliary cutting blade device is supported by the cutting unit via a connection / release mechanism and held at a predetermined ground height, and can be retracted backward when receiving a pressing force from the front,
Behind each support arm, a buffer means for buffering the backward retracting operation of each support arm is arranged.

  According to the first aspect of the present invention, when the auxiliary cutting blade device receives a pressing force from the front, the auxiliary cutting blade device can be retracted backward, and the retracting operation of the auxiliary cutting blade device can be buffered by the buffer means. Therefore, the auxiliary cutting blade device can be prevented from being damaged.

Invention of Claim 2 is invention of Claim 1, Comprising:
The buffer means comprises a spring case that is retractable in the front-rear direction and attached to the body frame, and a compression spring that is housed in the spring case so as to be compressible in the front-rear direction.
In the support arm, a contact piece protrudes toward the back spring case,
When the support arm is retracted backward, the compression spring is compressed through a spring case that is retractable in the front-rear direction so that the retracting operation of the support arm is buffered.

  In the invention according to claim 2, since the compression spring is accommodated in the spring case, it is possible to prevent clogs and the like from being caught in the compression spring and to ensure a satisfactory buffering function of the compression spring. it can. Therefore, also from this point, the retracting operation of the auxiliary cutting blade device is firmly buffered by the buffering means, and the auxiliary cutting blade device is prevented from being damaged.

Invention of Claim 3 is invention of Claim 2, Comprising:
The contact piece is characterized in that the protrusion width protruding backward from the support arm can be finely adjusted.

  In the invention according to claim 3, since the protruding width of the contact piece can be finely adjusted, the timing at which the support arm and further the auxiliary cutting blade device is buffered by the buffering means is appropriately adjusted via the contact piece. can do.

  According to the present invention, when the auxiliary cutting blade device receives a pressing force from the front, the auxiliary cutting blade device can be retracted backward, and the retracting operation of the auxiliary cutting blade device can be buffered by the buffer means. It is possible to prevent the auxiliary cutting blade device from being damaged.

The left view of the combine which shows this embodiment. The right view of the combine. The perspective view of the auxiliary cutting blade apparatus seen from diagonally forward. The front view of an auxiliary cutting blade apparatus. The top view of an auxiliary cutting blade apparatus. The left view of an auxiliary cutting blade apparatus. The right view of an auxiliary cutting blade apparatus. The perspective explanatory view of the switching operation lever of the connection / release mechanism. The perspective view of the connection / release body and the hanging support body of the connection / release mechanism. Plane explanatory drawing of the connection / release body and drooping support body of a connection / release mechanism. Back surface explanatory drawing of the connection / release body of a connection / release mechanism, and a drooping support body. The left side explanatory drawing of the connection / release body of a connection / release mechanism, and a drooping support body. Exploded perspective view of the buffer means. Sectional left view of a buffer means. The conceptual diagram of the transmission structure of a combine.

  Embodiments of the present invention will be described below with reference to the drawings. A shown in FIGS. 1 and 2 is an ordinary combine (hereinafter simply referred to as “combine”).

[General overview of the combine]
The combine A has the cutting part 2 attached to the front end part of the traveling machine body 1 capable of self-running so as to be movable up and down. And the cutting part 2 is the main cutting blade apparatus 3 which cuts the tip side part from the middle part of the napping cereal, and the residue of the standing hair which the tip side part was cut off by the main cutting blade apparatus 3 The auxiliary cutting blade device 4 that cuts off from the knives is provided.

  As shown in FIGS. 1 and 2, the traveling machine body 1 has a machine body frame 11 installed between a pair of left and right traveling units 10 and 10. And on the left side of the machine body frame 11, a threshing portion 12 for threshing the side portion of the harvested cereal head and a sorting portion 13 for sorting the threshed grain are arranged in the upper and lower stages. A dust exhaust port 14 for discharging sawdust and the like to the field outside the machine is opened rearward. In addition, on the right side of the machine body frame 11, a driving unit 15 that performs a driving operation is disposed in the front part, and a grain storage unit that stores the grain (clean grain) selected by the screening unit 13 behind the driving unit 15. 16 is disposed, and a grain unloading part 17 for unloading the grains stored in the grain storing part 16 to the outside is provided at the rearmost part. Below the rear part of the operation unit 15, an engine 18 or the like as a prime mover unit serving as a power source is disposed.

  The mowing unit 2 is arranged at a rectangular cylindrical feeder house 20 with an axis line in the front-rear direction, a horizontally long bucket-shaped grain header 21 communicating with the front end of the feeder house 20, and a front lower end edge of the grain header 21. The provided clipper-shaped main cutting blade device 3, a pair of left and right weed bodies 22, 22 formed to extend forward from the front left and right side portions of the grain header 21, and a scraper disposed on the front upper side of the grain header 21. And a reel 23.

  The rear end portion of the feeder house 20 pivotally supports a cutting input shaft 65 (feeder house conveyor shaft), which will be described later, with the horizontal axis directed to the front portion of the threshing portion 12, and the lower surface portion of the feeder house 20 and the body frame 11. The lifting / lowering cylinder 24 is interposed between the front end portion and the lifting / lowering hydraulic cylinder 24 (see FIG. 3) is expanded and contracted, so that the cutting portion 2 can be lifted / lowered using the cutting input shaft 65 as a lifting / lowering fulcrum. Yes.

  Further, the cutting unit 2 includes a sub cutting blade device 4, which is configured in a clipper shape like the main cutting blade device 3, and is hung forward and downward at the front end portion of the body frame 11. Attached to the rear of the main cutting blade device 3. A feeder conveyor 25 is disposed in the feeder house 20, and a scraping auger 26 (platform auger) is mounted in the grain header 21 so as to be rotatable about a horizontal axis. The take-up reel 23 is mounted so as to be rotatable about an axis in the left-right direction, and is continuously driven toward the take-up auger 26 while rotating to the tip of the napped grain culm. The operation parts of the respective parts described above are configured to be interlocked with the engine 18 via respective interlocking mechanisms to be described later and to operate appropriately.

  In the combine A comprised in this way, in the agricultural field, the cutting part 2 is raised until it becomes a desired ground height (a cutting position of the napped grain basket), and the traveling machine body 1 is made to travel in that state. By doing so, the napped portion of the culm is divided by the weed bodies 22, 22, and the middle portion of the cereal is squeezed by the main cutting blade device 3 while the head portion of the sown cereal is raked by the rake reel 23. Cut the side of the tip. The tip side portion of the cereal that has been cut at a desired cutting position is scraped into the grain header 21 by the scraping auger 26 and supplied to the threshing section 12 through the feeder house 20 by the supply conveyor 25. The tip side portion of the cereal supplied to the threshing unit 12 is threshed by the threshing unit 12, and the grain threshed by the threshing unit 12 is subjected to a sorting process by the sorting unit 13. The grain (clean grain) subjected to the sorting process by the sorting unit 13 is stored in the grain storage unit 16. The grain stored in the grain storage unit 16 is appropriately carried out of the machine by the grain carrying-out unit 17. And the sawdust etc. which were separated from the grain by the threshing unit 12 are discharged from the dust outlet 14 to the field outside the machine. Further, the residue from which the tip side portion has been cut is cut from the stock base portion by the auxiliary cutting blade device 4 and left in the field.

[Description of characteristic configuration of auxiliary cutting blade device]
In the combine A configured as described above, the present embodiment is characterized in that the auxiliary cutting blade device 4 is supported. Hereinafter, the configuration of the auxiliary cutting blade device 4 and the auxiliary cutting blade device 4 are supported. The configuration will be described with reference to FIGS.

  That is, as shown in FIGS. 3 to 5, the auxiliary cutting blade device 4 is arranged in the left-right direction between the distal ends of a pair of left and right support arms 29, 30 formed to extend forward from the body frame 11 of the traveling body 1. A fixed-side cutting blade body 31 extending in the horizontal direction is installed, and a movable-side cutting blade body 32 extending in the left-right direction is arranged on the fixed-side cutting blade body 31 so as to be slidable back and forth in the left-right direction. 1 is configured such that one side portion (left side portion in the present embodiment) of the movable-side cutting blade body 32 is interlocked and connected to the engine 18 provided in 1 through a cutting blade body sliding mechanism 33.

  A support body 34 that supports the middle part of the cutting blade body sliding mechanism 33 is provided at the tip (front end) of the support arm 29 on one side (the left side in the present embodiment). The end portion of the cutting blade body sliding mechanism 33 is disposed at a position so as to be reciprocally movable in the left-right direction, and the residue (hereinafter, also referred to as “stalk heel”) cut at the terminal portion of the cutting blade body sliding mechanism 33. Is provided in one of the left and right directions of the traveling machine body 1 (in the present embodiment, the right side which is the inner side).

  The end portion of the cutting blade body sliding mechanism 33 is a rod-like interlocking coupling body (push-pull rod) 36 having an axis line in the left-right direction, and is formed in a disc shape in the middle of the interlocking coupling body 36. The laterally-feeding body 35 is attached in the shape of a bowl, and the left and right side surfaces of the stem-and-frame laterally-feeding body 35 are formed as flat working surfaces 35a and 35a. And the stalk lateral feed body 35 is reciprocated in the left-right direction integrally with the interlocking coupling body 36 that is reciprocated in the left-right direction (push-pull operation), and the stalk lateral feed body 35 is moved to the left-right side. When moved, the flat action surfaces 35a, 35a exert a full pressing action on stalks or the like that may stay on the front surface of the support 34 or on the stalks that may stay. Etc. to the left and right sides. Therefore, it is possible to steadily eliminate the stalks and the like remaining on the front surface of the support 34. That is, it is possible to prevent the trimmed stems from staying in the gap between the interlocking coupling body 36 and the support body 34.

(Explanation of right support arm)
As shown in FIG. 3 to FIG. 7 and FIG. 13, ring-shaped bearing bodies 39, 39 with axial lines directed in the left-right direction are provided on the left and right sides of the body frame 11 of the traveling body 1. The inner half portions of cylindrical arm support shafts 38 with the axis line directed in the left-right direction are pivotally fitted around the axis line so as to be rotatable. A pair of left and right support arms 29, 30 are formed to extend forward and downward from the peripheral surface of the outer half of each arm support shaft 38, 38, and both support arms 29, 39 are supported via bearing bodies 39, 39. 30 is configured to be swingable up and down, and the auxiliary cutting blade device 4 is installed between the tip portions of both support arms 29 and 30. As shown in FIG. 4, the support arm 30 on one side (right side in the present embodiment) has a tip side portion 30 b that is inclined along the slope Zn of the heel Z, and is on the heel Z side of the field G. It is trying to be located in.

  That is, the right support arm 30 is formed by a rectangular pipe-shaped proximal end side portion 30a and a distal end side portion 30b extending forward and downward. The proximal end side portion 30a is formed by extending straight in the front-rear direction, and the distal end side portion 30b extends in a bent shape from the position close to the front end of the traveling portion 10 on the right side of the traveling machine body 1 toward the inside downward. The one side end portion (right end portion in this embodiment) of the auxiliary cutting blade device 4 that is formed and connected to the front end side portion 30b is supported at a position immediately before the outer end of the right traveling portion 10. I am doing so. The tip side portion 30b is formed by integrally forming the arcuate base end 30c, the straight booklet 30d, and the arcuate tip 30e, and placing the auxiliary cutting blade device 4 at the cutting position. 30d is arranged to be inclined along the slope Zn of the ridge Z. In the tip side portion 30b formed in this way, it is possible to avoid residue from remaining in the tip side portion 30b arranged in an inclined manner, and to connect the base end side portion 30a and the main piece 30d. It is possible to avoid stress concentration from occurring at the arcuate base end 30 c or the arcuate tip 30 e that connects the main piece 30 d and the right end of the auxiliary cutting blade device 4. Further, the left support arm 29 is formed in a rectangular pipe shape extending straight forward and downward and in a straight shape.

  As shown in FIG. 5, the main cutting blade device 3 and the auxiliary cutting blade device 4 are formed by extending in the left-right direction, and the auxiliary cutting blade device 4 is formed to be shorter than the main cutting blade device 3. Then, the left and right side end portions 4a and 4b are arranged to be positioned inside the left and right side end portions 3a and 3b of the main cutting blade device 3, and the right support arm 30 is located on the heel Z side of the field G. The left and right other end portions (the left end portion 4a in this embodiment) are arranged inwardly larger than the connected left and right one end portions (the right end portion 4b in the present embodiment). That is, the distance D1 in the left-right direction between the left end portion 3a of the main cutting blade device 3 and the left end portion 4a of the sub cutting blade device 4 is equal to the right end portion 3b of the main cutting blade device 3 and the sub cutting blade device 4. It is formed to be wider than the distance D2 in the left-right direction with respect to the right end 4b.

  In the right support arm 30 formed in this way, when the cutting operation is performed, the right support arm 30 is positioned on the heel Z side of the farm field G, so that the traveling unit 10 of the traveling machine body 1 approaches the heel Z. It can be made to cut and run. At this time, the right support arm 30 positioned on the ridge Z side of the field G is formed with the main piece 30d of the tip side portion 30b in an inclined shape along the slope Zn of the ridge Z. It is possible to prevent the problem that the main piece 30d of the distal end side portion 30b of the 30 collides with the slope surface Zn of the ridge Z and collapses the ridge Z, and the remaining on the distal end side portion 30b of the support arm 29 is prevented. Soot retention and stress concentration can be avoided.

  And the right end part 4b of the auxiliary cutting blade apparatus 4 connected with the front end side part of the right side support arm 30 is supported in the position just before the outer side end of the right side traveling part 10 of the traveling machine body 1. Therefore, even when the outer end of the traveling unit 10 on the right side of the traveling machine body 1 is cut and traveled close to the reed Z, the right end 4b of the auxiliary cutting blade device 4 causes the problem that the reed Z is collapsed. Can be prevented.

  Moreover, the auxiliary cutting blade device 4 is arranged with its left and right side end portions 4a and 4b positioned inside the left and right side end portions 3a and 3b of the main cutting blade device 3, and is also positioned on the heel Z side of the field G. Since the left end 4a (on the uncut side) is arranged inwardly more than the right end 4b (on the cut side) connected to the right support arm 30, the left end on the uncut side It is possible to prevent the occurrence of inconvenience that the portion 4a cuts the raised hair when the machine body is turned, and the brushed hair tip part is left in the field G without being transported to the traveling machine body 1. As a result, cutting efficiency can be improved.

(Explanation of connection / release mechanism)
Between the cutting part 2 and the auxiliary cutting blade apparatus 4, as shown in FIGS. 8-12, the connection / release mechanism 40 which switches the cutting part 2 and the auxiliary cutting blade apparatus 4 to a connection state and a non-connection state is provided. It is installed. That is, the connection / release mechanism 40 is connected between the connection / release body 41 provided in the cutting unit 2 and the connection / release body 41 and the auxiliary cutting blade device 4 so as to be switched between a connected state and a non-connected state. A hanging support 43 and a switching operation mechanism 42 for switching the hanging support 43 and the connection / release body 41 to a connected state or a non-connected state are provided.

  The switching operation mechanism 42 has a switching operation lever 174 attached to the side operation column 90 of the driving unit 15 provided in the traveling machine body 1, and the connection / release body 41 is connected to the switching operation lever 174 via an interlocking wire 180 as an interlocking connection body. Linked together.

  In the connection / release mechanism 40 configured as described above, when the vehicle travels on the road or exceeds the ridge Z, the cutting unit 2 and the auxiliary cutting blade device 4 are connected to each other via the connection / release mechanism 40, and the same state The auxiliary cutting blade device 4 can also be integrally raised to the required height by raising the cutting part 2 at. Therefore, it is possible to prevent the auxiliary cutting blade device 4 arranged so as to be raised to the required height from colliding with the protrusions on the road and to avoid being damaged. Further, when the cutting operation is performed in the field G, the cutting unit 2 and the auxiliary cutting blade device 4 are disconnected from each other via the connection / release mechanism 40, so that the cutting unit 2 can be moved up and down as appropriate. Even when the cutting height by the cutting blade device 3 is changed, the auxiliary cutting blade device 4 can be held at a constant ground height.

  And the operation which switches the drooping support body 43 connected with the sub-cutting blade apparatus 4 and the connection / release body 41 provided in the cutting part 2 to a connection state or a non-connection state is easy by switching operation of the switching operation mechanism 42. It can be carried out. That is, by the switching operation of the switching operation mechanism 42, the cutting unit 2 and the auxiliary cutting blade device 4 can be switched to a connected state or a non-connected state.

  Moreover, the switching operation of the switching operation mechanism 42 is performed through the interlocking wire 180 by the operator sitting on the driving unit 15 easily operating the switching operation lever 174 attached to the side operation column 90 of the driving unit 15. The connected connection / release body 41 can be steadily operated to switch the cutting unit 2 and the auxiliary cutting blade device 4 to a connected state or a non-connected state.

(Explanation of buffer means)
The auxiliary cutting blade device 4 is supported by the cutting unit 2 via the connection / release mechanism 40 so as to be held at a predetermined ground height, and can be retracted backward when a pressing force is applied from the front. Behind the arms 29, 30, buffer means 46, 46 for buffering the retracting operation of the support arms 29, 30 to the rear (back side) are arranged. Since the buffer means 46 and 46 are similarly arranged behind the support arms 29 and 30, respectively, only the buffer means 46 arranged behind the support arm 29 will be described below.

  That is, the buffer means 46 includes a spring case 200 that is retractable in the front-rear direction and attached to the body frame 11, and a compression spring 201 that is housed in the spring case 200 so as to be compressible in the front-rear direction. The support arm 29 is provided with a contact piece 202 projecting toward the spring case 200 behind, and when the support arm 29 is retracted backward, the support arm 29 is compressed via the spring case 200 that is retractable in the front-rear direction. The spring 201 is compressed so that the retracting operation of the support arm 29 is buffered. The contact piece 202 protrudes rearward from the support arm 29, specifically, a protrusion width W protruding rearward from a vertical surface portion 221 of the mounting bracket 220 described later can be finely adjusted.

  In the buffer means 46 configured in this manner, when the auxiliary cutting blade device 4 receives a pressing force from the front, the auxiliary cutting blade device 4 retracts backward, so that the auxiliary cutting blade device 4 is pushed from the front. It is possible to prevent damage or the like due to pressure.

  And since the compression spring 201 is accommodated in the spring case 200, it is possible to prevent clogs and the like from being caught in the compression spring 201, and to ensure a satisfactory buffering function of the compression spring 201. Therefore, also from this point, the retracting operation of the auxiliary cutting blade device 4 is firmly buffered by the buffer means 46, so that the auxiliary cutting blade device 4 is prevented from being damaged.

  Moreover, since the protruding width W of the contact piece 202 can be finely adjusted, the timing at which the support arm 29 and further the auxiliary cutting blade device 4 is buffered by the buffer means 46 via the contact piece 202 is appropriately adjusted. can do.

[Specific description of characteristic configuration]
Next, the structure which supports the auxiliary cutting blade apparatus 4 is demonstrated more concretely, referring FIGS. 3-14. That is, the auxiliary cutting blade device 4 is configured so that the movable cutting blade body 32 formed by extending in the left-right direction is reciprocally slidable in the left-right direction on the fixed side cutting blade body 31 formed by extending in the left-right direction. It is mounted and configured. At the front of the body frame 11, the base end portions (rear end portions) of the pair of left and right support arms 29 and 30 are pivotally supported by arm support shafts 38 and 38 whose axis lines are directed in the left and right directions. The auxiliary cutting blade device 4 is installed between the 30 front end portions (front end portions) so that the auxiliary cutting blade device 4 can be moved up and down.

  Then, the auxiliary cutting blade device 4 uses the floating support mechanism 45 to place the cutting blade bodies 31 and 32 in close proximity to the field G plane in a floating state (a state suspended from a position away from the field scene). It is possible to keep the cutting height from the field G plane where the sub-cutting blade device 4 cuts the residual residue so that it can be transferred along the G plane. The floating support mechanism 45 includes a connection / release mechanism 40 that allows the auxiliary cutting blade device 4 to be switched between a connected state and a non-connected state to the feeder house 20 of the cutting unit 2, and a buffer that buffers the backward movement of the auxiliary cutting blade device 4. Means 46.

(Specific description of coupling / release mechanism)
That is, as described above, the connection / release mechanism 40 includes the connection / release body 41, the switching operation mechanism 42, and the hanging support body 43, and the middle portion of the left support arm 29 and the left side wall of the feeder house 20. The cutting portion 2 and the auxiliary cutting blade device 4 can be switched between a connected state and a non-connected state.

  The connecting / releasing body 41 is a U-shaped flat piece 140 that is extended in the vertical direction and opened on the right side, and a pentagonal plate-like mounting plate that is attached so as to close the right end of the main piece 140. 141, and the attachment plate 141 is attached to the left side wall 20a of the feeder house 20 in a superposed state. A long guide hole 142 extending in the vertical direction is formed on the left side wall of the main piece 140. A front opening 143 and a rear opening 144 are formed on the front wall upper portion and the rear wall upper portion of the main piece 140 so as to face each other in the front-rear direction. A sliding body 145 formed in the shape of a square block is disposed in the main piece 140, and a sliding connection pin 146 protrudes from the sliding body 145 to the left side. The sliding connection pin 146 is placed in the guide slot 142. The sliding body 145 is slidable up and down along the guide long hole 142 through the sliding connection pin 146. Reference numerals 147 and 148 denote pin insertion holes formed in the middle part of the main piece 140 so as to be spaced apart in the vertical direction and opposed to the front wall and the rear wall, and each of the pin insertion holes 147, 147 or 148, 148 In the meantime, a lowering restriction pin 149 for restricting the lowering of the sliding body 145 is inserted in a detachable manner and horizontally mounted, and the lowering restriction position of the sliding body 145 can be adjusted by the lowering restriction pin 149.

  At the lower part of the mounting plate 141, a restriction arm support shaft 150 is provided to project to the left side at the lower right side of the main piece 140, and the restriction arm 151 is pivoted to the restriction arm support shaft 150 so as to be swingable back and forth. I support. The restricting arm 151 is formed by a vertically extending piece 152 extending in the up and down direction and a front extending piece 153 extending forward from the upper end of the vertically extending piece 152, and a boss portion 154 on the restricting arm support shaft 150. And the lower end portion of the vertically extending piece 152 is continuously provided on the peripheral surface of the boss portion 154.

  The restricting arm 151 pivotally supported by the restricting arm support shaft 150 is capable of moving forward and backward in a transverse penetrating manner in the front opening 143 and the rear opening 144 of the main piece 140. The front extension piece 153 has a fitting recess 155 that is fitted and locked to the lower end portion of the sliding body 145 from the lower side at the upper end edge of the front extension piece 153 so that the front extension extends forward. The lower end portion of the sliding body 145 is fitted and locked to the piece 153 via the fitting recess 155 so that the sliding movement of the sliding body 145 is restricted. The operating arm 160 is provided on the peripheral surface of the boss portion 154 so as to extend rearward, and the vertical swinging motion of the regulating arm 151 is interlocked with the vertical swinging motion of the operating arm 160.

  A torque spring 156 is wound around the outer peripheral surface of the restriction arm support shaft 150, and one end 157 of the torque spring 156 is locked to the vertically extending piece 152, while the torque spring is fixed to the spring locking plate 158 attached to the mounting plate 141. The other end 159 of 156 is locked, and the restriction arm 151 is urged to rotate clockwise around the restriction arm support shaft 150 by the torque spring 156 when viewed from the left side. Reference numeral 161 denotes a guide body protruding rearward from the rear wall of the main piece 140. The guide body 161 guides the front extension piece 153 that moves forward and backward in the front-rear direction from the left and right sides, and extends forward. The piece 153 has a function of guiding so as to firmly enter the front opening 143 and the rear opening 144.

  The switching operation mechanism 42 is attached to the upper part of the left side wall 90a, which is the outer wall of the side operation column 90, by overlapping the plate-like lever support 170 in a surface contact state, and from the upper end edge of the lever support 170 to the lever guide body. The lever guide body 171 is provided with a guide groove 172 extending in the front-rear direction. A locking groove 173 is formed in communication with the front end of the guide groove 172. A middle portion of the switching operation lever 174 whose axis is directed in the vertical direction is inserted into the guide groove 172 so that the middle portion is guided to the guide groove 172.

  The lever support 170 is provided with a lever pivot 175 that is positioned directly below the lever guide body 171, and a lever support shaft 176 that protrudes leftward from the lever pivot 175. The lever support shaft 176 is rotatably fitted with a lower boss portion 177 whose axis is directed in the left-right direction, and an upper boss portion 178 whose axis is directed in the front-rear direction on the upper surface of the lower boss portion 177. A base end portion of a switching operation lever 174 bent rearward is inserted into the upper boss portion 178 so as to be rotatable.

  The switching operation lever 174 is pivotally supported along the guide groove 172 around the lever support shaft 176 so as to be swingable back and forth, and is switched around the base end portion of the switching operation lever 174 that is rotated forward. The operation lever 174 is turned leftward so that it can be locked in the locking groove 173. An action lever 179 is provided on the peripheral surface of the lower boss portion 177 so as to extend downward, and an interlocking wire 180 is interposed between the action lever 179 and the operation arm 160 described above.

  The interlocking wire 180 is formed of a tubular flexible outer wire 181 and a flexible inner wire 182 that is slidably inserted into the outer wire 181. The outer wire 181 locks the base end portion 184 to the first wire receiver 183 protruding from the rear portion of the mounting plate 141, while the distal end portion 186 is connected to the second wire receiver 185 protruding from the front portion of the lever support 170. Locked. The inner wire 182 connects the proximal end portion 187 to the operating arm 160 and connects the distal end portion 188 to the action lever 179.

  The hanging support 43 connects the upper end of a plate-like vertical extending piece 190 extending in the vertical direction to a sliding connection pin 146 protruding leftward from the sliding body 145, and the lower end of the vertical extending piece 190. A plate-like left-hand extending piece 191 is formed by extending rightward from the left side to the left-hand extending piece 191, and upper and lower through holes 192 are formed in the left-hand extending piece 191, and a cylindrical support is formed in the circular upper and lower through-holes 192. The cylindrical piece 193 is inserted into the penetrating standing state, and the supporting cylindrical piece 193 is fixed to the outer surface of the vertically extending piece 190 via the bracket 194.

  A hanging rod 195 having an axis line in the vertical direction is inserted into the support cylinder piece 193, and a circular hook-shaped upper locking piece 196 is attached to the upper end portion of the hanging rod 195, and the upper portion of the support cylinder piece 193 is While the locking piece 196 is locked from above, the lower end portion of the hanging rod 195 is pivotally supported and connected to the middle portion of the left support arm 30 via the pivotal support portion 197. A circular hook-shaped lower locking piece 198 is attached to the upper surface of the hanging rod 195 in an overhanging manner, and the support cylinder piece 193 and the hanging rod 195 are interposed between the lower locking piece 198 and the left extension piece 191. A compression spring 199 wound around the outer peripheral surface and formed in a coil shape is interposed.

  When the auxiliary cutting blade device 4 receives an upward force (push-up) external force from the field G or the like, the drooping rod 195 is lifted and slid, and the sliding motion is the elasticity of the compression spring 199. It is buffered by the urging force to prevent the connecting portion of the hanging support 43 from being damaged.

  In the connection / release mechanism 40 configured as described above, when the switching operation lever 174 is rotated forward (switching operation), the action lever 179 is rotated counterclockwise around the lever support shaft 176 as viewed from the left side. Thus, the inner wire 182 is pulled and slid toward the action lever 179 side. At this time, the middle part of the switching operation lever 174 can be released from the switching operation lever 174 by being engaged with the engagement groove 173. Then, the action lever 179 is rotated counterclockwise in the left side view against the elastic biasing force of the torque spring 156 around the restriction arm support shaft 150 and is integrated with the action lever 179 via the boss 154. Further, the restricting arm 151 is also rotated counterclockwise as viewed from the left side. At this time, the sliding body 145 can be slid to the most elevated position via the drooping support body 43 by lowering the cutting part 2 to the lowest position. The front extension piece 153 can be disposed at a position directly below the sliding body 145 by causing the front opening 143 and the rear opening 144 to advance in a transverse penetrating manner.

  Therefore, when the cutting part 2 is raised to a predetermined non-harvesting work height (for example, the height over the shore or the road traveling height), the lower end of the sliding body 145 is fitted into the fitting recess 155 of the front extension piece 153. As a result, the sliding movement of the sliding body 145 is restricted, and the cutting unit 2 and the auxiliary cutting blade device 4 are integrally connected via the sliding body 145 so that the auxiliary cutting blade device 4 is desired. Raised to position.

  Further, by lowering the cutting part 2 to the lowest position, the sliding body 145 is slid to the highest position via the hanging support 43, and the lower end of the sliding body 145 is moved from the fitting recess 155 of the front extension piece 153. Release the mating. Subsequently, when the middle of the switching operation lever 174 is unlocked from the locking groove 173 and the operating hand is released from the switching operation lever 174, the restriction arm 151 is extended forward by the elastic biasing force of the torque spring 156. The piece 153 is rotated clockwise around the restriction arm support shaft 150 in the left side view, and the front extending piece 153 is retracted and pulled out from the front opening 143 and the rear opening 144.

  Therefore, even if the cutting unit 2 is raised to a predetermined position, the sliding member 145 is not restricted from being lowered by the lowering restriction pin 149 because the downward extension of the sliding member 145 is not restricted by the front extension piece 153. Until then, the cutting part 2 and the auxiliary cutting blade device 4 are in a disconnected state, and the auxiliary cutting blade device 4 is maintained in a floating state. That is, the switching operation mechanism 42 is switched to bring the cutting unit 2 and the auxiliary cutting blade device 4 into a non-connected state via the connecting / releasing body 41, so that the main cutting blade device 3 can select the desired cereal. The auxiliary cutting blade device 4 can be placed in a floating state independently of the main cutting blade device 3 while being raised at the cutting position.

(Specific description of buffer means)
As shown in FIGS. 13 and 14, the buffer means 46 has a rear portion fixed to a buffer means stay 203 suspended from the left front portion of the machine body frame 11 and is disposed so as to protrude forward. The spring case 200 provided in the buffer means 46 is formed of a cylindrical case 204 and a square box-shaped case 205 having an opening at the front end and the lower half of the lower half, and the cylindrical case 204 is formed in the front half of the square box-shaped case 205. The second half is slidably inserted in the front-rear direction.

  A circular lid piece 206 is fitted and locked to the peripheral edge of the front end of the cylindrical case 204 from the front, and a rod insertion hole 207 that opens in the front-rear direction is formed at the center of the lid piece 206. Through the front rod insertion hole 207, a sliding rod 208 having an axis line in the front-rear direction is inserted, and a rod locking piece 209 provided at the front end of the sliding rod 208 is brought into contact with the front surface of the lid piece 206. And a rear rod insertion hole 212 is formed in the center of the rear wall 210 of the square box case 205 so as to open in the front-rear direction, and the cylindrical guide piece 211 is inserted into the rear rod insertion hole 212. The rear portion of the sliding rod 208 is slidably passed back and forth, and the female screw portion 214 is screwed onto the male screw portion 213 formed on the rear surface of the sliding rod 208 so that the rear wall 210 of the square box-shaped case 205 The female threaded portion 214 is locked via a cylindrical guide piece 211.

  In the spring case 200, a compression spring 201 wound around the outer peripheral surface of the sliding rod 208 and formed in a coil shape is arranged, and the front end of the compression spring 201 is brought into contact with the rear surface of the lid piece 206, while the square box The rear end of the compression spring 201 is brought into contact with the rear wall 210 of the shaped case 205. On the rear wall 210 of the square box-shaped case 205, the upper edge thereof extends upward and is bent into a hook shape to integrally form a connecting piece 215, and is squarely attached to the buffer means stay 203 via the connecting piece 215. A box-shaped case 205 is attached.

  A mounting bracket 220 for mounting the abutting piece 202 is attached to the middle part on the back side of the left support arm 29. The mounting bracket 220 has a rectangular plate-like vertical surface portion 221 and a lower edge of the vertical surface portion 221. The horizontal plane portion 222 extends horizontally from the front to the left, and the left and right side surface portions 223 and 223 extend from the left and right side edges of the horizontal plane portion 222 and the vertical plane portion 221.

  The mounting bracket 220 is attached by fitting the front end portions of the left and right side surface portions 223 and 223 to the back side middle portion of the left support arm 29. A contact piece insertion hole 224 that opens in the front-rear direction is formed in the vertical surface portion 221, and a nut 225 that is a female screw portion is fixed to the inner surface (front surface) of the vertical surface portion 221 in alignment with the contact piece insertion hole 224. The contact piece 202 is inserted into the contact piece insertion hole 224 from the rear, and a bolt 226 that is a contact piece male screw portion formed in the front half of the peripheral surface of the contact piece 202 is screwed to the nut 225. .

  The contact piece 202 can be finely adjusted in the protruding width W of the contact piece 202 by adjusting the screwing of the nut 225 to advance and retract the bolt 226 in the front-rear direction. A rear end portion of the contact piece 202 is provided with a contact portion 230 whose rear surface is in contact with the front surface of the rod locking piece 209. Reference numeral 227 denotes a fastening nut screwed to the bolt 226, and reference numeral 228 denotes a washer. 229 is an interference avoidance hole formed on the rear wall of the left support arm 29 to avoid interference with the tip of the bolt 226.

(Description of the auxiliary cutting blade device drive mechanism)
The auxiliary cutting blade device 4 is linked to the engine 18 via the auxiliary cutting blade device drive mechanism 50. That is, the auxiliary cutting blade device drive mechanism 50 is interposed between the forward / reverse transmission shaft 51 horizontally mounted on the same axis as the cutting input shaft 65 described above and the movable cutting blade body 32 to transmit forward / reverse transmission. The rotational force from the shaft 51 is transmitted as a pushing / pulling sliding force to the movable cutting blade body 32. The auxiliary cutting blade device drive mechanism 50 includes an upstream chain transmission mechanism 52 and a downstream cutting blade sliding mechanism 33.

  The chain transmission mechanism 52 includes the above-described forward / reverse transmission shaft 51, an eccentric rotary shaft 53 that is installed horizontally in parallel below the shaft, and a cutting blade body protruding / input sprocket 54, 55 (see FIG. 15), the transmission chain 56 is wound. Reference numeral 57 denotes a tension arm for tensioning the transmission chain 56.

  The cutting blade body sliding mechanism 33 includes an eccentric rotating body 58 attached to the eccentric rotating shaft 53, a swing rotating shaft 60 having a rear end connected to the eccentric rotating body 58 via a swing converting body 59, and swinging. A swing drive arm 61 having a base end portion (upper end portion) attached to the front end portion of the rotation shaft 60 and an interlocking coupling body 36 having a left end portion connected to a distal end portion (lower end portion) of the swing drive arm 61 are provided. The right end of the interlocking connection body 36 is interlocked and connected to the left side of the movable cutting blade body 32 via an interlocking connection bracket 62. A support body 34 erected in a state orthogonal to the distal end portion (front end portion) of the support arm 30 is formed in a rectangular cylinder shape and rises forward and upward. A bearing body 63 is interposed on the left side wall of the support body 34. Thus, the front portion of the oscillating rotary shaft 60 is pivotally supported around its axis. Reference numeral 64 denotes a cover body that covers the cutting blade body sliding mechanism 33, and the cover body 64 is detachably attached to the left support arm 30.

  In the auxiliary cutting blade device drive mechanism 50 configured as described above, the one-way rotation of the eccentric rotation shaft 53 is converted into the swing rotation of the swing rotation shaft 60 (reciprocating rotation that rotates forward and backward within a certain range). The distal end side of the dynamic drive arm 61 is swung in the left-right direction, and the movable-side cutting blade body 32 and the fixed-side cutting blade body are reciprocated in the left-right direction via the interlocking coupling body 36. 31 cooperates to cut the residue of the field from the plant base.

  The main cutting blade device 3 is provided with a fixed-side cutting blade body 27 and a movable-side cutting blade body 28 as in the above-described sub-cutting blade device 4, and reciprocally slides the movable-side cutting blade body 28 in the left-right direction. The movable-side cutting blade body 28 and the fixed-side cutting blade body 27 cooperate with each other so as to cut the nappings in the field from the tip portion.

[Specific description of the aircraft]
A pair of left and right cutting posts 67, 67 are erected on the front end of the body frame 11, and both ends of the cutting input shaft 65 are connected to the cutting posts 67, 67 via cutting bearing bodies 68, 68, respectively. The part is pivotably supported. A forward / reverse switching case 66 for the harvesting device 3 is attached to the left harvesting column 67, and the harvesting input shaft 65 and the forward / reverse transmission shaft 51 are horizontally mounted on the same axis. The beater output sprocket 69 and the cutting blade output sprocket 54 are coaxially attached. The rear ends of the feeder house 20 are rotatably supported by the left and right cutting posts 67, 67 via a cutting input shaft 65. The entire harvesting device 3 is supported on the harvesting input shaft 65 via the feeder house 20 so as to be movable up and down. In addition, a beater 71 for cutting grain input is pivotally supported between the left and right harvesting columns 67 and 67 via a beater shaft 70.

  As shown in FIG. 1, the beater 71 is provided on the feed end side of the supply conveyor 25 and is put into the handling port of the threshing unit 12 by the beater 71. A handling cylinder 72 is rotatably supported in the handling chamber of the threshing device 9 via a handling cylinder shaft 75. On the lower side of the handling cylinder 72, a receiving net 73 for allowing the grains to leak is stretched. Note that a spiral screw blade-shaped intake blade 74 protrudes radially outward from the outer peripheral surface of the front portion of the barrel 72.

  As shown in FIG. 1, the sorting unit 13 is provided with a grain sorting mechanism 77 disposed below the receiving net 73. The grain sorting mechanism 77 includes a grain pan, a chaff sheave, a grain sheave, a Strollac, and the like. And a swing fan 78 for supplying specific wind to the swing separator 78 and the like. The threshing that has been threshed by the handling cylinder 72 and leaked from the receiving net 73 is separated from the grain (the most important one such as a refined grain) by the specific gravity sorting action of the swing sorter 78 and the wind sorting action of the Kara fan 76. It is configured such that it is selected and extracted as a mixture of grain and straw (second thing such as grain with branches) and sawdust.

  Below the swing sorter 78, a first conveyor mechanism 79 and a second conveyor mechanism 80 as a grain sorting mechanism 77 are provided. The grain (first thing) dropped from the swing sorter 78 by the sorting of the swing sorter 78 and the Kara fan 76 is stored in the grain storage unit 16 by the first conveyor mechanism 79 and the lifting conveyor 81. . The mixture of grain and straw (second product) is returned to the sorting start end side of the swing sorting plate 78 via the second conveyor mechanism 80 and the second reduction conveyor 82 and is re-sorted by the swing sorting plate 78. The Waste dust and the like are discharged from the dust outlet 14 at the rear of the traveling machine body 1 to the field.

  As shown in FIGS. 1 and 2, the operation unit 15 includes a front operation column 89, a side operation column 90, and a driver seat 91 on which an operator is seated. The front operation column 89 is provided with a control lever 92 for changing the course of the traveling machine body 1, and the side operation column 90 is provided with a speed change lever 93 for switching the moving speed of the traveling machine body 1. Further, a roof 95 for awning is attached to the upper side of the operation unit 15 via a sun visor support 94.

  As shown in FIGS. 1, 2, and 15, the traveling unit 10 has driving wheels 97 and driven wheels 98 attached to the front and rear portions of the traveling frame 96, and a crawler belt 99 is wound around these moving wheels. A mission case 100 is interposed between the drive wheels 97 of the pair of left and right traveling units 10 and 10 via traveling drive shafts 101 and 101. The mission case 100 includes a traveling hydraulic pump and a hydraulic motor. A hydraulic continuously variable transmission 102 for shifting is provided.

[Explanation of combine transmission structure]
Next, the transmission structure of the combine A will be described with reference to FIG. In other words, the red fan support shaft 112 that supports the red fan 76 is linked to the drive shaft 110 provided in the engine 18 via the first transmission belt mechanism 111. The first conveyor shaft 114 is linked to the Kara fan support shaft 112 via the second transmission belt mechanism 113, and the second conveyor shaft 116 is linked to the first conveyor shaft 114 via the third transmission belt mechanism 115. The swinging sorter operating shaft 118 is linked to the second conveyor shaft 116 via a fourth transmission belt mechanism 117.

  A threshing countershaft 120 is interlocked to the Kara fan support shaft 112 via a fifth transmission belt mechanism 119. A handling cylinder shaft 75 is linked to the threshing counter shaft 120 via a gear case 121. The beater shaft 70 is linked to the threshing counter shaft 120 via a sixth transmission belt mechanism 122. A forward / reverse transmission shaft 51 is linked to the beater shaft 70 via a seventh transmission belt mechanism 123. 83 is a beater input sprocket. As described above, the movable-side cutting blade body 32 is interlocked and connected to the forward / reverse transmission shaft 51 via the auxiliary cutting device drive mechanism 50.

  The cutting input shaft 65 linked to the forward / reverse transmission shaft 51 via the reverse rotation switching case 66 is linked to the supply conveyor 25 and linked to the cutting counter shaft 125 via the eighth transmission belt mechanism 124. doing. The cutting counter shaft 125 is interlocked with the scraping auger 26 via the ninth transmission belt mechanism 126, and is interlocked with the scraping reel 23 via the tenth transmission belt mechanism 127. The movable cutting blade body 28 of the main cutting blade device 3 is interlocked and connected via a mechanism 128.

  An input shaft 130 of the hydraulic continuously variable transmission 102 is linked to the drive shaft 110 provided in the engine 18 via an eleventh transmission belt mechanism 129. A cooling fan 132 is linked to the engine 18 via a fan drive shaft 131, and the fan drive shaft 131 is carried out in the grain storage part 16 and the grain carry-out part 17 via a conveyor transmission mechanism 133. Conveyors 134 and 135 are linked and connected.

A Combine 1 Traveling machine body 2 Cutting part 3 Main cutting blade device 4 Sub cutting blade device 30 Support arm 40 Connection / release mechanism 41 Connection / release body 42 Switching operation mechanism 46 Buffering means

Claims (3)

While the traveling machine body is provided with a cutting part having a main cutting blade device that cuts the tip part of the raised hair,
In the traveling machine body, a combine provided with a sub cutting blade device that cuts the residue of the napped hairs whose head portion has been cut by the main cutting blade device,
A base frame of a pair of left and right support arms extending forward and downward is pivotally supported on the machine frame of the traveling machine body via an arm support shaft having an axis line in the left-right direction between the front ends of both support arms. A secondary cutting blade device was installed,
The auxiliary cutting blade device is supported by the cutting unit via a connection / release mechanism and held at a predetermined ground height, and can be retracted backward when receiving a pressing force from the front,
A combiner characterized in that a buffer means for buffering the backward movement of each support arm is arranged behind each support arm. The buffer means comprises a spring case that is retractable in the front-rear direction and attached to the body frame, and a compression spring that is housed in the spring case so as to be compressible in the front-rear direction.
In the support arm, a contact piece protrudes toward the back spring case,
2. When the support arm is retracted backward, the compression spring is compressed through a spring case that is retractable in the front-rear direction so that the retracting operation of the support arm is buffered. Combine as described.   3. The combine according to claim 2, wherein the contact piece can be finely adjusted in a protruding width protruding backward from the support arm.

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