JP6288989B2 - Agricultural machine - Google Patents

Description

  The present invention relates to an agricultural machine that can easily change the depth of a groove.

  Conventionally, for example, an agricultural machine described in Patent Document 1 is known.

  This conventional farm work machine includes, for example, a machine body connected to the rear part of a traveling vehicle such as a tractor, a rotary body provided on the machine body so as to be rotatable in the vertical direction, and a lower part of the rotary body via a rotary shaft. A groove forming body that is rotatably provided to form a groove in the field, and a grounding body that is provided at a lower portion of the rotating body via a rotation shaft and that is configured to rotate and that sets the depth of the groove formed by the groove forming body. The rotation center axis of the groove forming body and the rotation center axis of the grounding body are located on the same line. And when changing the depth of the groove | channel formed in a groove | channel formation body, the grounding body from which an outer diameter differs is selected, and it replaces | exchanges for this selected grounding body.

Japanese Utility Model Publication No. 1-125008

  However, in the conventional agricultural machine, since it is necessary to replace the grounding body when changing the depth of the groove formed by the groove forming body, it may take time to change the depth of the groove. .

  This invention is made | formed in view of such a point, and it aims at providing the agricultural machine which can change the depth of a groove | channel easily.

According to a first aspect of the present invention, there is provided an agricultural machine connected to a traveling vehicle, an adjustable vertical position on the aircraft, a gauge wheel means that contacts a farm field, and a vertical rotating mechanism provided on the aircraft. A rotating body, a groove forming body that is provided on the rotating body and that forms a groove in a field, and a grounding body that is provided on the rotating body and sets a depth of the groove formed by the groove forming body. And when the rotating body rotates with respect to the machine body by adjusting the vertical position of the gauge wheel means with respect to the machine body, the lower end position of the groove forming body and the lower end of the grounding body are based on the rotation of the rotating body. The distance to the position changes.

According to a second aspect of the present invention, there is provided an agricultural machine connected to a traveling vehicle, an adjustable vertical position on the aircraft, a gauge wheel means that contacts the field, and a vertical rotating mechanism provided on the aircraft. A rotating body, a groove forming body that is provided on the rotating body so as to be rotatable about a first rotation center axis, and that forms a groove in a field, and the rotation body has a second rotation different from the first rotation center axis. rotatably provided around a central axis, said a grounding member for setting the depth of the groove formed in the groove forming member, said rotating member said the vertical position adjustment of the gauge wheels means for said machine body When rotating with respect to the machine body, the distance between the lower end position of the groove forming body and the lower end position of the grounding body changes based on the rotation of the rotating body.

The agricultural machine according to claim 3 is the agricultural machine according to claim 1 or 2, wherein a tubular member rotatably provided in the machine body is slidably inserted into the tubular member, and a lower end portion is rotated. A rod rotatably attached to the moving body and formed with a plurality of holes, a first pin inserted into one of the holes, and an upper end of the first pin and the tubular member A first spring provided between the first pin, a second pin inserted into another hole of the plurality of holes, and a second pin provided between the second pin and a lower end of the cylindrical member. 2 springs.

The farm machine according to claim 4 is the farm machine according to any one of claims 1 to 3, wherein the gauge ring means has a gauge ring positioned in front of the grounding body in a side view.

  According to the present invention, since the distance between the lower end position of the groove forming body and the lower end position of the grounding body changes based on the rotation of the rotating body, the depth of the groove formed by the groove forming body can be reduced. Can be easily changed.

It is a side view of the agricultural working machine which concerns on one embodiment of this invention. It is a partial top view of an agricultural working machine same as the above. It is a fragmentary perspective view of an agricultural working machine same as the above. It is a side view of the suppression wheel part of an agricultural working machine same as the above. It is a top view of a pressure wheel part same as the above. It is a rear view of the pressure wheel part same as the above. It is a side view in the state where the transmission case of the agricultural working machine same as the above stood. It is a side view in the state where the transmission case of the agricultural working machine same as the above fell.

  An embodiment of the present invention will be described with reference to FIGS.

  In the figure, reference numeral 1 denotes an agricultural machine. The agricultural machine 1 is connected to the rear part of a tractor (not shown), which is a traveling vehicle, for example, sowing while moving forward (traveling direction) on the field by forward traveling of the tractor. This is a multi-till type no-tillage sowing machine. That is, this agricultural working machine 1 is a seeder that does not include a tilling part (rotary).

  As shown in FIG. 1 and FIG. 2, the farm work machine 1 includes a machine body 2 that is detachably connected to a three-point link part (a farm work machine lifting part) at the rear of the tractor. An input shaft 4 in the front-rear direction is rotatably provided on the shaft support 3 at the center in the left-right direction of the body 2. The input shaft 4 is connected to the PTO shaft at the rear of the tractor via a transmission joint.

  On both the left and right sides of the front part of the machine body 2, gauge wheel means 6 for grounding to the field is provided so that the vertical position can be adjusted. Each gauge ring means 6 includes a gauge ring mounting arm 8 having a gripping portion 7 at its upper end, and a gauge ring that is a grounding ring that is rotatably attached to the lower end of the gauge ring mounting arm 8 and contacts the surface of the field. 9.

  The gauge wheel mounting arm 8 is formed with a plurality of holes 8a arranged at intervals in the vertical direction. A pin hole 5 a is formed in the cylindrical holder portion 5 of the machine body 2. Then, by inserting the retaining pin 20 into the one hole 8a selected from the plurality of holes 8a and the pin hole 5a of the holder 5, the gauge ring mounting arm 8 can be It is attached to the holder part 5 via a stop pin 20. In addition, it is possible to adjust the vertical position of the gauge ring means 6 with respect to the machine body 2 by changing the hole 8a into which the stop pin 20 is inserted (see FIGS. 7 and 8).

  Groove forming means 11 for forming sowing grooves m, which are linear grooves along the traveling direction, on the surface portion of the field are provided at a plurality of positions spaced in the left-right direction in the front part of the machine body 2. ing. The agricultural machine 1 includes a sowing means 21 sowing seeds, for example, seeds a and fertilizer b, in a sowing groove m formed in a concave shape on the surface of the field by the groove forming means 11, and the sowing means. The pressure-reducing wheel 22 that suppresses the covering soil covering the seed a and the fertilizer b sown in 21 while rotating in a predetermined direction, and the soil adhering to the outer peripheral surface of the pressure-reducing wheel 22 are scraped off and removed. A plurality of soil removal means 23 are provided for dropping to a position near the front of the pressure wheel 22 in order to use as a soil covering for seeds (a soil covering the seed a and the fertilizer b).

  Here, each seeding means 21 seeds, for example, seed a in the seed hopper 26 and fertilizer b in the fertilizer hopper 27 into the seeding groove m at regular intervals. Note that the seeding means 21 may be a seeding method for seeding only seed a in the seeding groove m, for example.

  Each seeding means 21 has a flexible seed guide hose 28 having an upper end connected to the lower part of the seed hopper 26. The lower end portion of the seed guide hose 28 is connected to the upper end portion of a seed guide tube 29 which is a bent tube, and the seed outlet 29a at the lower end portion of the seed guide tube 29 is a side of the positioning disk 30 which is a disk-shaped positioning body. Open in the vicinity.

  When the feeding rotary body (not shown) in the seed hopper 26 rotates and the seed a is fed out from the seed hopper 26, the fed seed a is fed into the seed guide hose 28 and the seed guide tube 29. It is discharged from the seed outlet 29a through the inside, and then hits the positioning disk 30 and the direction changes vertically downward and falls into the seeding groove m.

  Each seeding means 21 has a flexible fertilizer guide hose 31 having an upper end connected to the lower portion of the fertilizer hopper 27. A lower end portion of the fertilizer guide hose 31 is connected to an upper end portion of a fertilizer guide tube 32 that is a bent tube, and a fertilizer outlet 32a at the lower end portion of the fertilizer guide tube 32 is opened near the side of the positioning disk 30.

  When the feeding rotary body (not shown) in the fertilizer hopper 27 rotates and the fertilizer b is fed out from the fertilizer hopper 27, the fed fertilizer b is fed into the fertilizer guide hose 31 and the fertilizer guide tube 32. It is discharged from the fertilizer outlet 32a through the inside, and then hits the positioning disk 30 to change its direction downward vertically and falls into the seeding groove m.

  On the other hand, the positioning disk 30 is mounted on a disk mounting plate 35 attached to a projecting arm 34 projecting downward from a pressure-reducing wheel mounting arm 33 that rotatably supports the pressure-reducing wheel 22, and a shaft 36 in the left-right direction. It is attached to be rotatable through. The positioning disk 30 is positioned along the vertical plane, and guides the seed a and the fertilizer b into the sowing groove m by the side surface on one side.

  Each pressure-reducing wheel 22 performs soil covering pressure-reducing work while rotating in a predetermined direction behind the positioning disk 30 of the seeding means 21. The pressure-reducing wheel 22 rotates in a predetermined direction (rotation direction shown in FIG. 4) by a force received from the field side while being in contact with the field.

  As shown in FIGS. 3 to 6, each pressure-reducing wheel 22 is a pair of left and right pressure-reducing wheel members 41 in a disc shape that is positioned in a V shape (including a substantially V shape) in a front view. These pressure-reducing wheel members 41 squeeze the cover soil made of fine soil removed from the outer peripheral surface of the pressure-reducing wheel 22 and compress it into a mountain-shaped cross section.

  Each pressure-reducing wheel member 41 is rotatably attached to left and right attachment portions 42 at the lower end portion of the pressure-reducing wheel attachment arm 33 via a shaft 43 inclined with respect to the left-right direction. Each pressure-reducing wheel member 41 includes a disc-shaped disc portion 46 that rotates about a shaft 43, and a flange portion that is integrally connected to the outer peripheral end of the disc portion 46 and gradually increases in diameter toward the outside. It is composed of a truncated cone-shaped conical plate portion 47 having a head cone shape.

  Four fan-shaped through holes 48 are formed in the disc portion 46. The truncated conical plate portion 47 is formed with a plurality of triangular cutouts 49 arranged at intervals in the circumferential direction. Then, the covering soil is pressed down on the outer peripheral surface of the truncated conical plate portion 47 and pressed into a mountain-shaped cross section (see FIG. 6).

  In addition, a plate-shaped soil entry prevention body (guard) 50 for preventing soil from entering between the V-shaped disk portions 46 that are spaced apart from each other is disposed in front of the pressure reducing wheel 22. . The soil entry preventing body 50 is formed in a curved plate shape having a substantially triangular shape that is narrower toward the lower end. Further, the pressure-reducing wheel mounting arm 33 can be rotated up and down around the rotation fulcrum portion 45, and the vertical position of the pressure-reducing wheel 22 can be adjusted by the adjusting means 40.

  Each soil removing means 23 removes the soil on the surface portion of the farm field adhering to the outer peripheral surface of the pressure wheel 22 in front of the upper portion of the pressure wheel 22 and drops it to the front of the pressure wheel 22. That is, each soil removing means 23 is disposed in close contact with the upper front portion of the outer circumferential surface of the pressure wheel 22 so that the soil removed from the pressure wheel 22 is dropped to the vicinity of the front of the pressure wheel 22. Has been.

  As shown in FIGS. 3 to 6, each soil removing means 23 has a scraper 51 that is a pair of left and right rectangular plate-like soil removers positioned opposite to each other. The soil scraped and removed from the outer peripheral surface of the truncated conical plate portion 47 of the pressure wheel 22 falls to the front of the central portion in the left-right direction of the pressure wheel 22.

  In other words, the fine soil scraped off by the left and right scrapers 51 flies in a direction approaching each other so as to go to the sowing groove m (a direction inclined in the sowing groove side with respect to the front-rear direction in plan view). As a result, the sowing groove m is filled, and the desired amount of covering soil covering the seeds (seed a and fertilizer b) is raised. The raised covering soil (the soil adhering to the pressure wheel 22) is pressed down by the pressure wheel members 41 of the pressure wheel 22 and pressed into a cross-sectional mountain shape.

  Each scraper 51 is detachably attached to both left and right ends of a scraper attachment plate 52, which is a plate-like scraper attachment member, by attachment tools (for example, bolts and nuts) 53. The scraper mounting plate 52 is fixed to the lower surface of the intermediate portion in the longitudinal direction of the pressure reducing wheel mounting arm 33.

  Each scraper 51 is made of, for example, a metal plate bent at one intermediate position, and is integrally connected to a mounting plate portion 56 attached to the scraper mounting plate 52 and a rear end portion of the mounting plate portion 56. It is comprised with the earth | ground removal board part 57 of the front descending | tilting shape provided. Then, the free end portion, which is the rear end portion of the soil removing plate portion 57, comes into linear contact (sliding contact) with the upper front side portion of the outer peripheral surface of the truncated conical plate portion 47 of the pressure reducing wheel member 41. It has become. The length dimension of the contact portion 58 is longer than the width dimension of the outer peripheral surface of the truncated conical plate portion 47. The length dimension of the contact portion 58 and the width dimension of the outer peripheral surface of the truncated conical plate portion 47 may be the same.

  Further, the pair of scrapers 51 are positioned so as to have a C shape (including a substantially C shape) in plan view, and the separation distance between both contact portions 58 is larger than the separation distance between both front end portions. Long (see FIG. 5).

  On the other hand, each groove forming means 11 is a rotating body provided on the rotating fulcrum 10 of the main frame 61 of the main body 2 so as to be rotatable in the vertical direction, as shown in FIGS. A case (for example, a chain case) 71 is provided. Then, the transmission case 71 rotates in the vertical direction so that the lower end side moves up and down around the rotation fulcrum portion 10 in the left-right direction located on the upper end side.

  In the lower part of the transmission case 71, a sowing groove m is formed on the surface portion of the field while forcibly rotating in a predetermined direction by the power from the input shaft 4 side (driving rotation around the first rotation center axis A). A coulter 72, which is a disk-shaped groove forming body, is provided so as to be rotatable around a horizontal first horizontal rotation axis A located at the center thereof. That is, a groove forming coulter 72 is rotatably provided at the lower portion of the transmission case 71 via the rotary shaft 73 that rotates together with the chain in the transmission case 71. The outer peripheral portion of the coulter 72 is a groove forming blade portion 74 that enters the surface portion of the field, and the blade portion 74 is formed with a plurality of semicircular concave portions 75 arranged at equal intervals in the circumferential direction. ing.

  The lower end of the transmission case 71 is sown by traveling on the field while rotating in a predetermined direction (driven rotation about the second rotation center axis B) with a force received from the field while in contact with the field. A coulter gauge cylinder 76, which is a short cylindrical cylindrical grounding body for setting the depth of the groove m, is provided so as to be rotatable around a horizontal second horizontal rotation center axis B located at the center thereof. ing.

  That is, a coulter gauge cylinder 76 as a restricting body is provided at the lower end portion of the transmission case 71 so as to be rotatable via the support shaft 77 in the left-right direction. In other words, the coulter gauge cylinder 76 is rotatably supported by the support shaft 77 that is a fixed shaft that is fixedly provided on the side surface of the lower end of the transmission case 71, and the support force is received by the force received from the field side. It rotates around an axis (second rotation center axis B) 77. The round shaft-shaped support shaft 77 is fixed to, for example, a central portion (including a substantially central portion) of the lower end side surface of the transmission case 71 by welding or the like.

  The coulter gauge cylinder 76 has, for example, a cylindrical portion 78 whose outer peripheral surface is formed in a cylindrical surface centered on the second rotation center axis B, and four outer end portions on the inner surface of the cylindrical portion 78. A fixing portion 79 having a substantially cross shape when viewed from the side is fixed, and a cylindrical portion 79a at the center of the attaching portion 79 is rotatably attached to the outer peripheral side of the support shaft 77.

  The outer diameter dimension of the coulter gauge cylinder 76 is smaller than the outer diameter dimension of the coulter 72. The coulter gauge cylinder 76 is positioned so as to overlap the coulter 72 as a whole in a side view. The coulter gauge cylinder 76 is disposed at a position near one side of the transmission case 71, and the coulter 72 is disposed at a position near the other side of the transmission case 71.

  Further, a lower end portion of a vertically extending rod 82 is rotatably attached to an attachment portion 81 on the upper rear side of the transmission case 71. The upper end side of the rod 82 is slidably fitted and inserted into a cylindrical member 83 that is rotatably attached to the main frame 61. A plurality of holes 85 are formed in the rod 82, and a coil-shaped first spring 87 is disposed between the first pin 86 inserted into one hole 85 and the upper end of the tubular member 83, and the like. A coiled second spring 89 is disposed between the second pin 88 inserted into the hole 85 and the lower end of the cylindrical member 83. A coulter cover 90 is disposed above the coulter 72.

  Here, as is clear from FIG. 1 and the like, the first rotation center axis A that is the rotation center of the coulter 72 is a line that passes through the axis of the rotation shaft 73, and the second rotation center that is the rotation center of the coulter gauge cylinder 76. The rotation center axis B is a line passing through the axis of the support shaft 77. The first rotation center axis A and the second rotation center axis B are different from each other and are not located on the same line. B is located on the tip side that is the lower end side of the transmission case 71 with respect to the first rotation center axis A. That is, the rotation shaft 73 and the support shaft 77 are not located on the same axis, and the support shaft 77 of the coulter gauge cylinder 76 is shifted downward from the rotation shaft 73 of the coulter 72.

  For this reason, the distance between the lower end position of the coulter 72 and the lower end position of the coulter gauge cylinder 76 is changed based on the rotation of the transmission case 71 around the rotation fulcrum 10 with respect to the machine body 2, so The depth changes.

  For example, FIG. 7 shows a state where the transmission case 71 is standing, that is, a state where the transmission case 71 is inclined at an inclination angle θ1 with respect to the vertical direction. In this state, the lower end position of the coulter 72 and the lower end position of the coulter gauge cylinder 76 are shown. The distance is k1.

  Further, for example, FIG. 8 shows a state in which the transmission case 71 is in a lying state, that is, a state in which the transmission case 71 is inclined at an inclination angle θ2 with respect to the vertical direction, and in this state, the lower end position of the coulter 72 and the lower end position of the coulter gauge cylinder 76 are shown. The distance to is k2 (> k1). The depth “k2” of the seeding groove m shown in FIG. 8 is deeper than the depth “k1” of the seeding groove m shown in FIG.

  Thus, in the case of the configuration shown in FIGS. 7 and 8 (configuration with a gauge wheel), when the transmission case 71 rotates with respect to the machine body 2 by adjusting the vertical position of the gauge wheel means 6 with respect to the machine body 2, this transmission case. Based on the rotation of 71, the distance between the lower end position of the coulter 72 and the lower end position of the coulter gauge cylinder 76 (depth of the sowing groove m) changes. That is, the sowing groove m is deepened as the transmission case 71 rotates upward, and the sowing groove m is shallow as the transmission case 71 rotates downward.

  In the case of the configuration without the gauge ring means 6 (configuration without the gauge ring), the transmission case 71 is moved relative to the machine body 2 by adjusting the vertical position of the agricultural machine 1 with respect to the tractor by the three-point link portion (hydraulic device) of the tractor As the transmission case 71 rotates, the distance between the lower end position of the coulter 72 and the lower end position of the coulter gauge cylinder 76 changes.

  The airframe 2 has a main frame 61, left and right side frames 62, a rear frame 63, a step 64, a connecting link 65, a transmission case rear frame 66, and the like, as shown in FIGS. . The transmission case rear frame 66 is rotatably attached to a lower rear mounting portion 60 of the transmission case 71, and a pressure reducing wheel mounting arm 33 is provided at a rotation fulcrum at an intermediate portion in the longitudinal direction of the transmission case rear frame 66. It is attached via 45 so that it can rotate.

  Next, the operation and the like of the farm work machine 1 will be described.

  For example, in a clay-like field, when the agricultural machine 1 is connected to the rear part of the tractor and moved in the direction of travel by the forward traveling of the tractor, the coulter 72 of the groove forming means 11 has a desired depth on the surface part (uncultivated soil) of the field. The sowing groove m is formed, and the sowing means 21 drops seed a and fertilizer b from the seed outlet 29a and the fertilizer outlet 32a to sow in the sowing groove m at the rear, so The member 41 crushes the covering soil covering the seed a and the fertilizer b into a mountain shape.

  At this time, the covering soil to be pressed down by the pressure-reducing wheel member 41 of the pressure-reducing wheel 22 is soil that has been scraped from the outer peripheral surface of the pressure-reducing wheel member 41 by the scraper 51 of the soil removing means 23 and is reduced. The soil is attached to the outer peripheral surface of the member 41.

  That is, for example, in a clay field, clayey soil adheres to the outer peripheral surface of the pressure-reducing wheel member 41 of the pressure-reducing wheel 22, and this adhered soil is removed from the pressure-reducing wheel member 41 by the scraper 51 of the soil removing means 23. It is scraped off from the outer peripheral surface and becomes a fine soil suitable for covering soil during this scraping. The fine fine soil falls toward the sowing groove m and enters the sowing groove m, and becomes a covering soil for the seed material, and rises on the surface of the field. It is crushed and compacted at 22.

  For example, in order to change and adjust the depth of the sowing groove m formed by the coulter 72 of the groove forming means 11 in order to sow different kinds of seeds a, the gauge ring mounting arm 8 into which the stop pin 20 is inserted. What is necessary is just to adjust the up-and-down position of the gauge ring means 6 with respect to the body 2 by changing the hole 8a.

  When the gauge ring means 6 is moved and adjusted with respect to the holder 5 of the machine body 2 in the vertical direction, the coulter 72 is adjusted based on the rotation of the transmission case 71 suspended from the main frame 61 of the machine body 2. The distance (the depth of the sowing groove m) between the lower end position and the lower end position of the coulter gauge cylinder 76 changes.

  According to the agricultural machine 1, the first rotation center axis A of the groove forming coulter 72 and the second rotation center axis B of the coulter gauge cylinder 76 for setting the groove depth are located on the same line. Without changing the distance between the lower end position of the coulter 72 and the lower end position of the coulter gauge cylinder 76 based on the rotation of the transmission case 71, the depth of the seeding groove m formed by the coulter 72 Can be easily changed.

  In addition, the sowing groove m can be appropriately formed in the field with the disc-shaped coulter 72, and the depth of the sowing groove m can be appropriately set with the cylindrical coulter gauge cylinder 76.

  Furthermore, the coulter gauge cylinder 76 having a cylindrical shape whose outer peripheral surface is formed into a cylindrical surface is configured to travel on the field while rotating in a predetermined direction with a force received from the field while being in contact with the field. The depth of the seed groove m formed at 72 can be set appropriately.

  Moreover, since the soil adhering to the outer peripheral surface of the pressure wheel 22 can be removed and used as a covering soil for the seeded material, the seeded material, for example, seed a and fertilizer b, can be used regardless of the soil soil quality. It can be stably and appropriately covered with a desired amount of soil covering.

  Further, since the soil removing means 23 is disposed in the vicinity of the upper front side portion of the outer peripheral surface of the pressure reducing wheel 22, it is possible to appropriately remove the soil adhering to the outer peripheral surface of the pressure reducing wheel 22, and the removed soil Can be used as a covering soil for seeds.

  Note that the seeding means 21 is not limited to seeds and fertilizer sowing, and for example, seeding only one of seeds and fertilizer, seeding with a drug as a seed, etc. may be used.

  Further, the grounding body such as the coulter gauge cylinder 76 is rotatably supported by the support shaft 77 fixed to the rotating body such as the transmission case 71, and is not limited to the one rotated by the force from the field side, For example, the rotating body may be provided so as to be rotatable via a rotating shaft, and driven and rotated together with the rotating shaft by power from the input shaft 4 side.

  Further, the grounding body may be configured by, for example, an arcuate plate-like sliding member that is fixed to the rotating body and slides on the field.

  In addition, the groove forming body such as the coulter 72 is preferably driven and rotated by receiving power from a power transmission means such as a chain in the transmission case 71. For example, the groove forming body is rotated by a force from the field side or does not rotate. Things may be used.

  Further, for example, a support shaft (rotation fulcrum) 77 of a coulter gauge cylinder 76 that travels along the travel trace of the rear wheel (not shown) of the tractor and the gauge wheel 9 so that the depth of each seeding groove m is constant. Alternatively, the rear wheel of the tractor and the configuration where the other coulter gauge cylinder 76 that does not travel along the trace of travel of the gauge wheel 9 may be arranged at a position higher than the support shaft (rotation fulcrum) 77.

1 Agricultural machine
2 aircraft
6 gauge wheel means
9 gauge wheel
71 Transmission case as a rotating body
72 Coulter, a groove forming body
76 Coulter gauge tube as a grounding body
82 rod
83 tubular member
85 holes
86 pin 1
87 1st spring
88 pin 2
89 Second spring A First rotation center axis B Second rotation center axis m Seeding groove which is a groove k1, k2 distance

Claims (4)

A fuselage connected to the traveling vehicle;
Gauge wheel means that can be adjusted to adjust the vertical position on this machine body,
A rotating body provided on the airframe so as to be vertically rotatable ;
A groove forming body provided on the rotating body and forming a groove in the field;
A grounding body that is provided on the rotating body and sets a depth of a groove formed by the groove forming body;
When the rotating body rotates with respect to the machine body by adjusting the vertical position of the gauge ring means with respect to the machine body, the lower end position of the groove forming body and the lower end position of the grounding body are based on the rotation of the rotating body. Agricultural machine characterized by the change in the distance. A fuselage connected to the traveling vehicle;
Gauge wheel means that can be adjusted to adjust the vertical position on this machine body,
A rotating body provided on the airframe so as to be vertically rotatable ;
A groove forming body that is provided on the rotating body so as to be rotatable about the first rotation center axis, and that forms a groove in the field;
The rotating body is provided rotatably about a second rotation center axis that is different from the first rotation center axis, and includes a grounding body that sets a depth of a groove formed by the groove forming body,
When the rotating body rotates with respect to the machine body by adjusting the vertical position of the gauge ring means with respect to the machine body, the lower end position of the groove forming body and the lower end position of the grounding body are based on the rotation of the rotating body. Agricultural machine characterized by the change in the distance. A tubular member rotatably provided on the airframe;
A rod that is slidably inserted into the cylindrical member, a lower end is rotatably attached to the rotating body, and a plurality of holes are formed;
A first pin inserted into one of the plurality of holes;
A first spring provided between the first pin and the upper end of the tubular member;
A second pin inserted into another hole of the plurality of holes;
A second spring provided between the second pin and the lower end of the tubular member;
The agricultural machine according to claim 1, further comprising: The gauge ring means has a gauge ring located in front of the grounding body in a side view.
The agricultural machine according to any one of claims 1 to 3, wherein

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