JP5072011B2 - Granular material spreader - Google Patents

Description

  The present invention relates to a granular material spreader that delivers a predetermined amount of granular materials such as drugs, fertilizers, seeds, etc., and distributes them to the field, and in particular, when branching the transport path from the feeding device to the field into a plurality of branch paths, The present invention relates to a technique for equalizing the distribution amount of particulate matter entering each branch path.

Conventionally, in a granular material spreader that feeds granular materials such as chemicals, fertilizers, seeds, etc. and performs sowing, chemical spraying, fertilization, etc., by branching the transport route from the feeding device to the field into multiple branch routes Therefore, it is possible to spread multiple lines and spread with a small number of feeding devices, and reduce the number of parts to reduce the cost of the granular material spreader and improve the maintainability. In order to branch the granular material into a plurality of branch paths in this way, a bifurcated branch portion is provided in the middle of the transport path, and a granular material dispersing means is provided on the upstream side of the branch portion. By forming the inflow path of the granular material in a straight line, a granular material uneven distribution preventing structure (see, for example, Patent Document 1 and Patent Document 2) for preventing the uneven distribution of the granular material until entering the branched portion, or in the branched portion The valve body is provided with a valve body, and the granular material is alternately distributed to each branch path alternately at a constant cycle, or the distribution amount ratio of the distributed granular material is adjusted by the fixed angle of the valve body, etc. A granular material distribution control structure (see, for example, Patent Document 3 and Patent Document 4) that controls the distribution amount of the granular material when entering each branch path from the vehicle is known. Also, a plate-like branching section (hereinafter referred to as “diffusion plate”) is provided in the middle of the fall of the granular material on the field, and the granular material is allowed to collide with the diffusion plate to disperse widely around the diffusion plate. In addition, a fallen granular material dispersion structure (for example, Patent Document 5 and Patent Document 6) is also known in which a granular material is dropped toward a field with an infinite number of branch paths.
JP 2005-117913 A JP 11-289831 A Japanese Patent Laid-Open No. 9-289811 JP 2001-320925 A No. 7-50888 Utility Model Registration No. 2516890

  However, when using a slide-type feeding roll in which the length, position, etc. of the granular material feeding groove provided on the outer peripheral surface can be freely changed by sliding the constituent members fitted to each other, When using a granular material such as a fine drug that is difficult to disperse uniformly because it is too small or the granular material itself has poor fluidity (hereinafter referred to as “hardly dispersible particle”), When being fed out or immediately after being fed out, it is already unevenly distributed in the transport path. Therefore, the branch part also enters the branch part in a state of being unevenly distributed, and is distributed only to a specific branch path, so that there is a great difference in the amount of particulate matter sprayed from each branch path to the field. In this regard, in the granular material uneven distribution prevention structure, when the uneven distribution property of the granular material is high by using the slide-type feeding roll or the hardly dispersible particles, the uneven distribution property cannot be sufficiently eliminated and the uneven distribution is uneven. There is a problem that the branch part enters the branch part as it is, and the granular material is distributed to a specific branch path in a biased manner, resulting in a large difference in the amount of particulate matter sprayed from each branch path to the field. Further, neither the granular material distribution control structure nor the falling granular material dispersion structure discloses a technique for equalizing the distribution amount of the granular material to each branch path. Of the crotch branching to each branch path at the branch part (hereinafter referred to as “branch boundary part”) even in the normal case where the uneven distribution of the granular material is low Depending on the shape and size, the granular material cannot accurately collide with the boundary of the branch, and the granular material is distributed evenly on a specific branch path, and the amount of the granular material sprayed on the field is large. There was a problem of making a difference.

The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.
In Claim 1, it has a conveyance path which conveys the granular material paid out from the feeding apparatus to a spraying position, and the branch part which branches the granular material under conveyance into a plurality of branch paths in the middle part of the conveyance path In the provided granular material spreader, a guide body capable of guiding the flow of the granular material is provided on a branch boundary portion of the adjacent branch path on the upstream side of the branch portion in the transport path , A bottom surface portion that is tapered in plan view, which is inclined downward toward the branch boundary portion and is inclined downward as it advances in the forward direction, and a tapered left and right outer side of the inclined bottom surface portion. It comprises a pair of left and right side portions having a triangular shape in plan view, and is configured such that the distance between the left and right side portions becomes narrower as it approaches the branch boundary portion .
According to a second aspect of the present invention, in the granular material spreader according to the first aspect, a groove portion capable of restricting the flow of the granular material toward the branch boundary portion is formed on the bottom surface portion of the guide body. .

Since this invention was comprised as mentioned above, there exists an effect shown below.
That is, according to the first aspect of the present invention, there is provided a transport path for transporting the granular material fed from the feeding device to the spraying position, and a branch for branching the granular material being transported into a plurality of branch paths in the middle of the transport path. In the granular material spreader provided with a section, a guide body capable of guiding the flow of granular material is provided on the branch boundary portion of the adjacent branch path on the upstream side of the branch section in the transport path, so that the slide In order to use the feeding roll and the hardly dispersible grain of the formula, even when the granular material is fed out from the feeding device or immediately after being fed out, it is unevenly distributed by the guide body even if it is in a significantly unevenly distributed state. It is possible to collect the granular materials in one place and accurately guide them on the branch boundary, and distribute the particulates evenly to each branch path at the branch boundary, and the amount of granular material sprayed from each branch path to the field The difference between Te, it is possible to improve the uniformity spraying of the granules to the field.
In addition, the guide body is inclined downward toward the branch boundary portion, and the bottom surface portion having a tapered shape in a plan view that is inclined downward while being inclined downward as it advances in the forward direction, and the inclined bottom surface portion. Since it is composed of a pair of left and right side portions in a plan view that is erected from the tapered left and right outer sides, and the distance between the left and right side portions is made narrower as it approaches the branch boundary , from the feeding device The fed granular material is received on the bottom surface portion, and the left and right side portions are gradually collected at the outlet while regulating the granular material so as not to protrude from the bottom surface portion, and a specific amount of granular material is formed on the branch boundary portion. An object can be guided, a guide body with a simple configuration and excellent guidance accuracy is formed, and it is possible to reduce component costs and improve assembly and maintenance.
According to a second aspect of the present invention, the guide body has a bottom surface portion inclined downward toward the branch boundary portion, and the flow of the granular material can be regulated on the bottom surface portion toward the branch boundary portion. Since the groove portion is formed, the granular material fed from the feeding device is received on the bottom surface portion, and the granular material is gradually gathered at the outlet while being regulated so as not to protrude from the bottom surface portion by the groove portion of the bottom surface portion, A specific amount of granular material can be guided on the branch boundary, and a guide body with a simple structure and excellent guidance accuracy can be formed, so that the cost of parts can be reduced and the assemblability and maintainability can be improved.
Further , when the lower end from which the granular material flows out from the guide body is configured to be position-adjustable with respect to the branch boundary portion, the lower end of the guide body is connected to the branch boundary when the guide body is installed in the conveyance path. The initial mounting position can be finely adjusted so that it is on substantially the same vertical plane as the part, or it can be quickly returned to the original position even if it deviates greatly from the initial mounting position due to vibration or load applied to each member during work, It is possible to further improve the guidance accuracy of the granular material on the branch boundary portion, to distribute the granular material evenly by each branch path, and to further reduce the difference in the amount of granular material sprayed onto the field.

  Next, embodiments of the invention will be described. 1 is a left side view showing the overall configuration of a fertilizer seeding machine according to the present invention, FIG. 2 is a partially sectional view of the same plane, FIG. 3 is a left side view of a main part showing a seed transport path and a fertilizer transport path, FIG. Is a partial cross-sectional view of the left side of the main part showing the seed transport path, FIG. 5 is a front partial cross-sectional view of the main part, FIG. 6 is a perspective view, a side view, and a front view of the guide body. (A) is a perspective view, FIG. 6 (b) is a side view, FIG. 6 (c) is a front view, FIG. 7 is a perspective view of a guide body showing another mounting structure and a restricting structure, and FIG. FIG. 9 is a partial cross-sectional view of the left side of the main part showing another conveyance path.

  First, the whole structure of the fertilizer seeder 1 which is a granular material spreader concerning this invention is demonstrated with reference to FIG. 1 thru | or FIG. In the following description, the direction of the arrow A in FIG. 1 is defined as the “front” direction, and this direction coincides with the traveling direction of the body of the fertilizer seeding machine 1.

  The fertilizer seeding machine 1 includes a seed hopper 2, a seed feeding device 3, a fertilizer hopper 4, a fertilizer feeding device 5, a fixed frame 6, a main frame 7, groove forming portions 8L and 8R, soil covering disks 9L and 9R, a pressure reducing roller 10, and the like. Is done.

  The seed hopper 2 is a container for storing seeds. The seed hopper 2 is provided with an opening on the upper surface and the lower surface. A lid 2a is provided on the opening on the upper surface of the seed hopper 2, and the lid 2a is opened. The seed is replenished in the seed hopper 2. Further, the seed hopper 2 is detachably attached to the upper part of the seed feeding device 3, and the opening on the lower surface of the seed hopper 2 is configured to be opened and closed by a slide plate 2b. Even if the seeds are removed from the seed feeding device 3 while being stored, the seeds are not spilled from the opening on the lower surface, and the remaining seeds can be easily recovered.

  The seed feeding device 3 feeds seeds in the seed hopper 2 by a predetermined amount, and is arranged at the lower part of the seed hopper 2. The seed that has flowed into the seed feeding device 3 from the opening on the lower surface of the seed hopper 2 due to its own weight is fitted into a groove 65a provided on the outer peripheral surface of the slide-type feeding roll 65 in the seed feeding device 3, It is conveyed to the lower part of the seed feeding device 3 by the rotation of the feeding roll 65, is fed from the feeding port 63 on the lower surface of the seed feeding device 3, and flows down to the guide body 60 according to the present invention.

  The fertilizer hopper 4 is a container for storing fertilizer, and has openings on the upper surface and the lower surface. A lid 4a is provided on the opening on the upper surface of the fertilizer hopper 4, and the fertilizer is opened by opening the lid 4a. The fertilizer hopper 4 is replenished. Further, the fertilizer hopper 4 is detachably attached to the upper portion of the fertilizer feeding device 5, and the opening on the lower surface of the fertilizer hopper 4 is configured to be opened and closed by a slide plate 4 b, and the fertilizer is stored in the fertilizer hopper 4. Even if it is removed from the fertilizer feeding device 5 as it is, the fertilizer is not spilled from the opening on the lower surface, and the remaining fertilizer can be easily recovered.

  The fertilizer feeding device 5 feeds the fertilizer in the fertilizer hopper 4 by a predetermined amount, and is disposed at the lower part of the fertilizer hopper 4. The fertilizer that has flowed into the fertilizer feeding device 5 from the opening on the lower surface of the fertilizer hopper 4 due to its own weight is inserted into a groove (not shown) provided on the outer peripheral surface of the sliding feed roll 66 in the fertilizer feeding device 5. The fertilizer feeding device 5 is conveyed to the lower portion of the fertilizer feeding device 5 by the rotation of the feeding roll 66, and flows downward from the feeding port 64 on the lower surface of the fertilizer feeding device 5.

  The seed hopper 2 is detachably fixed to the rear portion of the fertilizer hopper 4 by locking members 2c and 2c, and the seed feeding device 3 is detachably fixed to the rear portion of the fertilizer feeding device 5. And the gear 67 provided in the rotating shaft 3a of the feeding roll 65 of the seed feeding apparatus 3 is meshed with the gear (not shown) provided in the rotating shaft 5a of the feeding roll 66 of the fertilizer feeding apparatus 5 and the rotation. The shaft 5a is rotationally driven by an external driving force input means such as a grounding wheel that rotates as the tractor travels. Thereby, the feeding roll 65 of the seed feeding device 3 and the feeding roll 66 of the fertilizer feeding device 5 are configured to be rotatable while maintaining a predetermined rotational speed ratio.

  Here, in the feeding rolls 65 and 66 of the seed feeding device 3 and the fertilizer feeding device 5 as described above, the length of the groove can be freely changed. For example, the feeding roll 65 of the seed feeding device 3 includes a main body roll 68 having a plurality of main body concave portions 68a on the circumference and a fitting having a fitting convex portion 69a fitted on the main body concave portions 68a on the circumference. The fitting projection 69a is fitted into the main body recess 68a and is slid in the direction of the rotating shaft 3a, whereby the inner wall of the main body recess 68a and the tip of the fitting projection 69a are formed. The groove length 65b of the groove 65a composed of the portion can be changed. Thereby, the amount of seeds or fertilizers accommodated in the groove 65a at a time can be adjusted to a desired value, and the fertilization operation while maintaining the seed dropping amount and the fertilizer dropping amount at a desired amount substantially constant. Sowing work can be performed. In the feeding rolls 65 and 66, the groove length 65b can be freely changed as described above. On the other hand, the groove 65a is formed so as to be deviated from the center in the axial direction, and the seed feeding position. Is also biased to one side from the axial center.

  In the seed feeding device 3, a brush 71 is fixed by a knob screw 72 on the upper rear portion of the feeding case 70 that houses the feeding roll 65, the rotation shaft 3 a, and the like. The seeds that come into contact with the periphery of the roll 65 are scraped off from the grooves 65a so that excess seeds are not fed out. In the fertilizer feeding device 5 as well, excess fertilizer is not fed out by the same configuration.

  Further, the fertilizer seeding machine 1 is fixed to the fixed frame 6 by fastening members 6a and 6b that are fastened to the front upper portion of the fixed frame 6 by fastening the front surface of the fertilizer feeding device 5 with bolts. It is fixed to a prismatic fixing member (not shown). The prism member is fixed to the rear part of the work vehicle so that the longitudinal direction thereof substantially coincides with the left and right direction of the work vehicle (not shown), and a plurality of fertilizer seeding seeders 1... The work vehicles can be fixed side by side in the left-right direction.

  The main frame 7 is a hollow box-shaped structure, and the rear ends of the parallel links 11 and 12 are pivotally supported at the front portion of the main frame 7. The front ends of the parallel links 11 and 12 are pivotally supported by the lower part of the fixed frame 6 so as to be rotatable. A winding spring 13 is interposed between a rotation pivot point on the main frame 7 side of the parallel link 11 and a rotation pivot point on the fixed frame 6 side of the parallel link 12. The main frame 7 is urged in a direction of rotating downward.

  As for the pressure reducing roller 10, a seeding groove is formed by the groove forming portions 8L and 8R, seeds are dropped into the seeding groove by the seed feeding device 3 and the seed transport path 61, and the soil is covered with the soil covering disks 9L and 9R. Later, the field is crushed and is disposed at the rearmost portion of the fertilizer seeding machine 1 and is rotatably supported at the rear end portion of the support arm 55 extending rearward of the main frame 7.

  The groove forming portion 8L is mainly composed of a groove forming disk 31L and an auxiliary disk 41L. Of these, the groove forming disk 31L is a substantially disk-shaped member for forming a seeding groove on the field surface. The auxiliary disk 41L has a function of assisting the formation of the sowing groove by the grooving disk 31L and a function of blocking so that the soil immediately after being discharged to the outside of the sowing groove does not fall into the sowing groove again. It is a substantially disk-shaped member. The groove forming disk 31L is pivotally supported by the support shaft 35L, and the auxiliary disk 41L is pivotally supported by the support shaft 15L. Similarly, the groove forming portion 8R includes a groove forming disk 31R and an auxiliary disk 41R. Of these, the groove forming disk 31R is a substantially disk-shaped member for forming a seeding groove on the field surface. 41R is a substantially disk shape that has the function of assisting the formation of the sowing groove by the grooving disk 31R and the function of blocking so that the soil immediately after being discharged to the outside of the sowing groove does not fall into the sowing groove again. It is a member. The groove forming disk 31R is pivotally supported by the support shaft 35R and the auxiliary disk 41R is pivotally supported by the support shaft 15R.

  The support shafts 15L and 15R project from the lower end of the support arm 14 to the left and right sides of the machine body, and the upper end of the support arm 14 is a mounting portion provided at the front end of the main frame 7. The supporting arm 14 can be fixed to the main frame 7 at a desired height by a locking bolt 16. Thereby, the depth of a pair of sowing grooves formed by the groove forming portions 8L and 8R can be adjusted to a desired depth.

  Further, a substantially central portion of the scraper support member 17 is fixed to a middle portion of the front surface of the support arm 14 from the left and right ends of the scraper support member 17 through the fixing members 18L and 18R. 19R is extended to the rear, and the rear ends of the scrapers 19L and 19R are in contact with the rear surface of the groove forming disks 31L and 31R in a state of being urged by the scrapers 19L and 19R, respectively. The soil or the like adhering to the outer surface of the groove disk 31L / 31R is peeled off. Further, scrapers 20L and 20R extend rearward from the upper and lower middle portions of the left and right side surfaces of the support arm 14, and the rear ends of the scrapers 20L and 20R are urged to the rear side of the inner side surfaces of the auxiliary disks 41L and 41R, respectively. In this state, the scrapers 20L and 20R are made to peel off and remove soil and the like adhering to the inner surfaces of the auxiliary disks 41L and 41R.

  Next, each conveyance route for conveying seeds and fertilizer from the feeding devices 3 and 5 to the field will be described with reference to FIGS. First, the seed transport path 61 is a path for transporting seeds fed by the seed feeding device 3 to a sowing groove in a field, and mainly includes a funnel 21, a waterproof cover 22, a funnel chute 23, and a branch chute that is a branching portion. 24, conveying pipes 25L and 25R, seeding nozzles 26L and 26R, and the like. Of these, the funnel 21 is a funnel-shaped member that expands upward, and the upper portion of the funnel 21 is connected to and communicated with the feeding port 63 of the seed feeding device 3.

  An upper end portion of a waterproof cover 22 is connected to the lower portion of the funnel 21, and the waterproof cover 22 is a substantially cylindrical member having a body portion formed in a bellows shape, and is made of a flexible resin, plastic, or the like. The waterproof cover 22 can be expanded and contracted when the main frame 7 swings with respect to the fixed frame 6 according to the unevenness of the field.

  An upper portion of a funnel chute 23 is connected to the lower end portion of the waterproof cover 22, and the funnel-shaped member that expands upward is provided with through holes 23 a and 23 a on the left and right side surfaces thereof. The funnel chute 23 is fixed to the upper rear portion of the main frame 7 by penetrating the pins 53 in the through holes 23a and 23a. The pin 53 can also function as a support frame that supports the guide body 60 by bringing the outer peripheral side surface thereof into contact with a bottom surface portion 60a of the guide body 60 described later from below.

  The upper end of the branch chute 24 is connected to the lower portion of the funnel chute 23. The branch chute 24 is a member that forms a branch portion of the seed transport path 61, and the lower end portion of the upper cylinder 24a that is a cylindrical member is The branching boundary 24d is branched to a cylindrical left branch cylinder 24b and a right branch cylinder 24c. Of these, the upper end portion of the upper cylinder 24 a is connected to the lower portion of the funnel chute 23. The main body of the branch chute 24 is rigid and difficult to deform. However, since the seed falling from the guide body 60 described later collides with the inner wall of the branch chute 24, plastic or It is preferable to use a soft material that can absorb impact, such as a resin.

  The lower ends of the left and right branch cylinders 24b and 24c of the branch chute 24 are connected to the upper ends of the transfer pipes 25L and 25R, respectively, and the transfer pipes 25L and 25R are cylindrical shapes made of flexible plastic or resin. It is comprised by the member of.

  Furthermore, the upper ends of the left and right seeding nozzles 26L and 26R are connected to the lower ends of the left and right transport pipes 25L and 25R, respectively, and the seeding nozzles 26L and 26R are cylindrical shapes that form the most downstream part of the seed transport path 61. It is comprised from the member of. Of these, the seeding nozzle 26L is disposed in a space sandwiched between the groove forming disk 31L and the auxiliary disk 41L of the groove forming portion 8L, and is supported by a support member 34L that supports the support shaft 35L via a bracket 42L. Is fixed. Similarly, the seeding nozzle 26R is also disposed in a space sandwiched between the groove forming disk 31R and the auxiliary disk 41R of the groove forming portion 8R, and is supported by a support member 34R that supports the support shaft 35R via a bracket 42L. Is fixed.

  By such a seed transport path 61, the seeds fed from the seed feeding device 3 can be branched by the branch chute 24, transported to the respective groove portions 8L and 8R, and dropped into a pair of right and left sowing grooves. In addition, the seed transport path 61 is configured to be inexpensive and simple, and the seeds can be dropped into a pair of left and right sowing grooves.

  Further, the fertilizer transport path 62 arranged in parallel with the seed transport path 61 is a path for transporting the fertilizer fed by the fertilizer feeding device 5 to the field, and mainly includes a funnel 27, a waterproof cover 28, a funnel chute 29, Consists of a conveyance tube 30 and the like. Of these, the funnel 27 is a funnel-shaped member that expands upward, and the upper portion of the funnel 27 is connected to and communicated with the feeding port 64 of the fertilizer feeding device 5.

  An upper end portion of a waterproof cover 28 is connected to the lower portion of the funnel 27. The waterproof cover 28 is a substantially cylindrical member having a body portion formed in a bellows shape, and is made of a flexible resin, plastic, or the like. The waterproof cover 28 can be expanded and contracted when the main frame 7 swings with respect to the fixed frame 6 according to the unevenness of the field.

  An upper portion of a funnel chute 29 is connected to the lower end of the waterproof cover 28. The funnel chute 29 is a funnel-shaped member that expands upward, and through holes 29a and 29a are formed on the left and right sides thereof. The funnel chute 29 is fixed to the front upper surface of the main frame 7 by penetrating the pins 54 in the through holes 29a and 29a.

  A lower end of the funnel 29 is connected to an upper end portion of the transport pipe 30, and the transport pipe 30 is a cylindrical member made of flexible plastic or resin. The opening of the part is arranged in a space sandwiched between the auxiliary disks 41L and 41R.

  By such a fertilizer transport path 62, the fertilizer fed from the fertilizer feeding device 5 can be dropped between the pair of auxiliary disks 41L and 41R, and even when the fertilizer jumps when dropped on the field, The auxiliary disks 41L and 41R serve as walls to prevent the fertilizer from falling into the sowing groove, and to prevent seed fertilizer failure.

  Next, a guide body 60 according to the present invention will be described with reference to FIGS. In the seed transport path 61, a support stay 73 having a triangular shape in a side view is erected from the inclined surface 23b inside the funnel chute 23, and the lower half of the fixing plate 74 is fixed to the vertical front side of the support stay 73. The guide body 60 according to the present invention is detachably fastened and fixed to the front surface of the upper half of the fixing plate 74 by a locking bolt 75.

  The guide body 60 includes a bottom surface portion 60a having a tapered shape in a plan view that is inclined downward and narrows as it advances in the forward direction indicated by an arrow A from a parallel portion, and tapered left and right outer sides of the bottom surface portion 60a. A pair of left and right side surface portions 60b and 60c having a triangular shape in plan view, and a fixed portion 60d having a rectangular shape in front view standing from the rear end of the parallel portion of the bottom surface portion 60a. A mounting hole 60e is formed in the center of the fixing portion 60d when viewed from the front. The fixing portion 60d is brought into contact with the upper portion of the fixing plate 74 from the front, and the fixing plate 74 is shown through the mounting hole 60e. The guide body 60 can be fastened and fixed to the fixing plate 74 by screwing the locking bolt 75 over the mounting hole.

  In such a configuration, as described above, when the groove 65a of the feeding roll 65 is formed so as to be biased to one side from the center in the axial direction, the seed 36 fed from the seed feeding device 3 is placed inside the funnel 21. It falls on the slope 21a. The seed 36 on the slope 21a rolls and falls into the waterproof cover 22 from the end of the slope 21a, and the waterproof cover 22 is formed in a bellows-like substantially cylindrical shape that expands downward. Therefore, the dropped seed 36 passes without contacting the inner wall of the waterproof cover 22 and falls to the funnel chute 23 communicated with the lower portion of the waterproof cover 22.

  In the funnel chute 23, the seed 36 that has fallen collides near the end of the bottom surface portion 60 a of the guide body 60, and then is regulated by the side surface portions 60 b and 60 c, while the bottom surface portion 60 a inclined forward and downward. Rolls up to the bottom end 60f without spilling from the side. The seed 36 flowing out from the lower end 60f flows down in the upper cylinder 24a of the branch chute 24 communicated with the lower part of the funnel chute 23, and becomes a branch boundary as a boundary when branching to the left and right branch cylinders 24b and 24c. It collides with the part 24d.

  At this time, it is preferable that the branch boundary 24d and the flow lower end 60f are on substantially the same vertical plane. As a result, the seed 36 that has flowed out of the funnel 23 falls on the inner wall surface of the upper cylinder 24a and rolls on the inner wall surface even when it falls in the space in the upper cylinder 24a and directly collides with the branch boundary 24d. Even when it collides with the branch boundary 24d, the seed 36 does not flow off the course up to the branch boundary 24d greatly, and the seed 36 can flow more evenly into the left and right branch paths 24b and 24c.

  The seeds 36 distributed to the left and right branch paths 24b and 24c in this way are transported to the groove forming portions 8L and 8R through the seeding nozzles 26L and 26R through the transport pipes 25L and 25R, respectively, and a pair of right and left seeding is performed. It is dropped into the groove.

  In this embodiment, since the slide-type feeding roll 65 is used, the position of the groove 65a is biased to one side from the center in the axial direction, and the present invention is applied when the seed 36 to be fed greatly deviates from the course to the branch boundary 24d. Although the case where it applied is demonstrated, as above-mentioned, also when a granular material is a hard-dispersible seed, a chemical | medical agent, a fertilizer, etc., the guide body 60 concerning this invention is applicable. That is, even if the seeds 36, which are hardly dispersible grains, are fed from substantially the center in the axial direction of the feeding roll 65 and are not dispersed in the funnel 21, the seeds 36 are unevenly distributed. When falling and colliding on the bottom surface portion 60a, the seeds 36 are collected on the bottom end 60f along the side surface portions 60b and 60c while rolling on the bottom surface portion 60a. Then, the collected seeds 36 flow down from the flow lower end 60f, and then flow down without greatly deviating from the course to the branch boundary 24d.

  That is, it has the seed conveyance path 61 which is a conveyance path | route which conveys the seed 36 which is the granular material paid out from the seed feeding apparatus 3 which is a feeding apparatus to a spraying position, It is conveying in the middle part of this seed conveyance path 61 In the fertilizer sowing machine 1 that is a granular material spreader provided with a branch chute 24 that is a branching part for branching the seed 36 into a plurality of branch pipes 24b and 24c that are a plurality of branch paths, Since the guide body 60 capable of guiding the flow of the seeds 36 is provided on the branch boundary portion 24d of the adjacent branch cylinders 24b and 24c on the upstream side, the slide-type feeding roll 65 and the hardly dispersible grains are used. Therefore, when the seed 36 is fed from the seed feeding device 3 or immediately after being fed, the seed body 36 is unevenly distributed by the guide body 60 even if the seed 36 is extremely unevenly distributed. The seeds 36 can be gathered in one place and can be accurately guided onto the branch boundary 24d. The seeds 36 are evenly distributed to the branch cylinders 24b and 24c at the branch boundary 24d, and the branch cylinders 24b and 24c are distributed. Thus, the difference in the amount of seed sprayed from the field to the field can be reduced, and the uniform sprayability of the seed 36 to the field can be improved.

  Further, the guide body 60 has a bottom surface portion 60a inclined downward toward the branch boundary portion 24d, and a pair of side surface portions 60b and 60c erected from the bottom surface portion 60a on the left and right in the inclination direction, Since the distance between the left and right side surface portions 60b and 60c becomes narrower as the branch boundary portion 24d is approached, the seed 36 fed from the seed feeding device 3 is received on the bottom surface portion 60a, and the left and right side surface portions 60b are received. 60c allows the seeds 36 to be gradually collected at the lower flow end 60f that is the outlet while regulating the seeds 36 so as not to protrude from the bottom surface part 60a, and a specific amount of seeds 36 can be induced on the branch boundary part 24d. The guide body 60 having a simple configuration and excellent guidance accuracy is formed, and it is possible to reduce the component cost and improve the assemblability and the maintainability.

  Next, another embodiment of the restricting structure for restricting the flow of the particulate matter on the bottom plate and the mounting structure of the guide plate will be described with reference to FIGS. In the mounting configuration as shown in FIG. 7, a support stay 73 having a triangular shape in side view is erected from the inclined surface 23 b inside the funnel chute 23, and the support stay 73 has a T-shape in front view on the vertical front side. A vertical column 77 a of a fixed plate 77 is fixed, and screw portions 77 c and 77 d protrude forward from the left and right sides of the front surface of the horizontal plate 77 b above the fixed plate 77.

  On the other hand, the guide body 76 has a tapered bottom surface portion 76a that is inclined downward and narrows in the forward direction, and a triangular triangle that is erected from the tapered left and right outer sides of the bottom surface portion 76a. A pair of left and right side surface portions 76b and 76c having a shape and a fixed portion 76d having a rectangular shape in front view standing upright from the rear end of the parallel portion of the bottom surface portion 76a. Long holes 76e and 76f that are long to the left and right are drilled in the left and right positions of the fixing portion 76d as viewed from the front, and the screw portions 77c and 77d are inserted into the long holes 76e and 76f. 79, the guide body 76 is fastened and fixed so that the left and right positions can be adjusted. Further, unlike the guide body 60, a plurality of groove portions 76h are formed on the bottom surface portion 76a so as to be directed toward the flow lower end 76g.

  As a result, the locking nuts 78 and 79 are loosened and the guide body 76 is moved to the left and right, and adjusted so that the flow lower end 76g is substantially on the same vertical plane as the branch boundary 24d. The guide body 76 can be fixed again by retightening, and the guide body 76 can be set at a position suitable for guiding the seed 36 to the branch boundary portion 24d. Although only the left and right positions are adjusted in the present embodiment, the vertical position and the front and rear position may be adjustable as necessary, and the adjustment direction and mechanism are not particularly limited.

  Further, the seeds 36 that have fallen on the bottom surface portion 76a are regulated by the side surface portions 76b and 76c so as not to spill from the side, but the repulsive force at the time of dropping is large, and the seeds 36 are vigorously sideways. In the case of rolling toward the bottom, the groove portion 76h serves as an obstacle to suppress the movement of the seed 36, and reliably guides the seed 36 along the groove portion 76h to the flow bottom 76g. In the present embodiment, the side surface portions 76b and 76c and the groove portion 76h are provided together as a structure for restricting the flow of the seeds 36. However, the groove portion 76h alone has a sufficient restriction effect.

  That is, since the flow lower end 76g from which the seed 36 that is a granular body flows out from the guide body 76 can be adjusted in position with respect to the branch boundary 24d, the guide body 76 is placed in the seed transport path 61 that is the transport path. The initial mounting position is finely adjusted so that the lower end 76g of the guide body 76 is substantially on the same vertical plane as the branch boundary 24d, and the initial mounting is performed by vibration and load applied to each member during work. Even if it is greatly deviated from the position, it can be quickly returned to the original position, the accuracy of guiding the seed 36 onto the branch boundary 24d is further increased, and the seed 36 is evenly distributed by the branch cylinders 24b and 24c as the branch paths. The difference in the amount of particulate matter sprayed on the field can be further reduced. A long hole is provided in the lateral plate 77 b above the fixing plate 77, and a screw portion protruding from the fixing portion 76 d of the guide body 76 is inserted into the long hole so that the guide body 76 is fixed to the fixing plate 77. It may be fastened and fixed to be adjustable in position.

  Further, the guide body 76 has a bottom surface portion 76a inclined downward toward the branch boundary portion 24d, and the flow of the seed 36, which is a granular material, is directed to the branch boundary portion 24d on the bottom surface portion 76a. Since the restrictable groove 76h is formed as described above, the seed 36 fed from the seed feeding device 3 is received on the bottom surface 76a, and the seed 36 is not protruded from the bottom surface 76a by the groove 76h of the bottom surface 76a. As a result, the specific amount of seeds 36 can be guided onto the branch boundary portion 24d, and a guide body 76 with a simple configuration and excellent guidance accuracy can be formed. As a result, assembly and maintenance can be improved.

  Further, in the mounting configuration as shown in FIG. 8, a support stay 80 having an inverted L-shape when viewed from the side is erected from the inclined surface 23 b inside the funnel chute 23, and on the front surface of the upper half of the support stay 80, The guide body 60 is fastened and fixed detachably by a locking bolt 75. On the other hand, a bolt 81 is fixed to the lower half of the support stay 80, and a threaded portion 81a of the bolt 81 is inclined rearward and downward so as to pass through a long hole 23c drilled in the left and right direction. The fixing nut 82 is screwed into the protruding end from the outside.

  Thereby, the fixing nut 82 is loosened and the guide body 60 is moved to the left and right, and adjusted so that the flow lower end 60f is substantially on the same vertical plane as the branch boundary 24d, and then the fixing nut 82 is retightened and the guide body is retightened. 60 can be fixed, and the guide body 60 can be set at a position suitable for guiding the seed 36 to the branch boundary 24d. In addition, the fixed nut 82 is provided outside the funnel chute 23 and is configured to be operable from the outside. Therefore, without removing peripheral members such as the waterproof cover 22, the state of spraying particulate matter from the outside While confirming the above, it is possible to finely adjust the mounting position of the guide body 60, further improve the accuracy of guiding the granular material onto the branch boundary portion 24d, and improve the work efficiency of the position adjustment work. .

  Next, another form of the granular material conveyance path will be described with reference to FIG. The transport path 83 is obtained by removing the bellows-like stretchable waterproof cover 22 and the funnel chute 23 from the seed transport path 61 and directly connecting the lower part of the funnel 84 to the upper part of the branch chute 24. However, although the number of parts is small and the configuration is simple, the branch chute 24 and the transport pipes 25L and 25R vibrate due to the unevenness of the field and the like, and the dropping position of the granular material slightly changes. Therefore, the transport path 83 is applied to a medicine or the like that does not require a very high positional accuracy compared to seeds.

  In the transport path 83, a long hole 70 a that is long in the left-right direction is formed in the side wall of the lower part of the feeding case 70, and a screw part of a bolt 85 fixed to the fixing part 60 d of the guide body 60 is formed in the long hole 70 a. 85a is inserted, and a fixing nut 86 is screwed into the protruding end of the screw portion 85a from the outside.

  Thereby, the fixing nut 86 is loosened and the guide body 60 is moved to the left and right to adjust the flow lower end 60f to be substantially on the same vertical plane as the branch boundary 24d, and then the fixing nut 86 is retightened and the guide body is retightened. 60 can be fixed, and even when the waterproof cover 22 and the funnel chute 23 are omitted, the guide body 60 can be set at a position suitable for guiding the drug 87 to the branch boundary 24d. In addition, the fixing nut 86 is provided outside the feeding case 70 and is configured to be operable from the outside, so that the dispersal of the medicine 87 is confirmed from the outside without removing the peripheral members, The mounting position of the guide body 60 can be finely adjusted, the guidance accuracy of the drug 87 onto the branch boundary 24d can be further increased, and the work efficiency of the position adjustment work can be improved.

  The present invention is a granular material spreader that feeds a predetermined amount of granular materials such as medicines, fertilizers, seeds and the like and spreads them on a field, and uses a branch chute or a diffusion plate as a transport path from the feeding device to the field. When branching to a plurality of branch paths, it can be applied to all the granular material spreaders in which the distribution amount of the granular material entering each branch path varies greatly depending on the granular material feeding position of the feeding device and the characteristics of the granular material. .

It is a left view which shows the whole structure of the fertilizer seeding machine concerning this invention. It is a plane partial sectional view similarly. It is a left view of the principal part which shows a seed conveyance path | route and a fertilizer conveyance path | route. It is a left side partial sectional view of an important part showing a seed conveyance course. It is a front fragmentary sectional view of the principal part. It is a perspective view of a guide body, a side view, and a front view, (a) is also a perspective view, (b) is also a side view, (c) is also a front view. It is a perspective view of the guide body which shows another attachment structure and a control structure. It is a side view of the principal part which shows another attachment structure. It is a left side partial sectional view of an important part showing another conveyance path.

DESCRIPTION OF SYMBOLS 1 Granules spreader 3 Feeding device 24 Branch part 24b * 24c Branch path 24d Branch boundary part 36 Granules 60 Guide body 60a Bottom surface part 60b * 60c Side surface part 61 Transport path 76g Flow bottom 76h Groove part

Claims (2)

A granular material spreader having a conveyance path for conveying the granular material fed from the feeding device to a spraying position, and having a branching portion for branching the granular material being conveyed into a plurality of branching paths in the middle of the conveyance path In this case, a guide body capable of guiding the flow of particulate matter is provided on the branch boundary portion of the adjacent branch path on the upstream side of the branch portion in the transport path, and the guide body faces the branch boundary section. The bottom surface of the planar view that is inclined downward and the width is narrowed as it progresses in the forward direction, and the triangular shape in plan view that stands upright from the tapered left and right outer sides of the inclined bottom surface portion. And a pair of left and right side portions, and the interval between the left and right side portions becomes narrower as it approaches the branch boundary portion . 2. The granular material spreader according to claim 1, wherein a groove capable of restricting the flow of the granular material toward the branch boundary is formed on the bottom surface of the guide body. .

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