JP2012110319A - Multi-line sowing machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve problems of a conventional multi-line sowing machine wherein time and effort is required to collect seeds by using a cleaner, etc. and the workability is impaired because respective feeding parts are detached from connection members, etc. after pulling a common rolling shaft inserted into of a sowing roll in the feeding parts, and as a result, seeds remaining in a seed case are scattered under the multi-line sowing machine from openings where the sowing rolls are disposed.SOLUTION: In the multi-line sowing machine, a feeding part unit 31 is integrally formed of feeding parts 36 including the sowing roll 40 mounted in the seed case 39, a connecting plate 37 which connects a plurality of rows of the feeding parts 36, and the common roll shaft 38 penetrating the sowing roll 40 in the axial direction to rotate. Attaching/detaching structures for easily attaching/detaching the feeding unit 31 are disposed at both ends of the feeding unit 31 and between main frames 3L and 3R constituting the outer frame of the multi-line sowing machine 1.

Description

  The present invention relates to a multi-row seeding machine for sowing a plurality of seeds at a time, and more particularly to an attachment / detachment structure in which a seed feeding portion can be easily attached and detached without using a tool.

  Conventionally, in a multi-row seeding machine used for multi-row sowing such as a nursery bed, a plurality of feeding portions are provided in the left-right direction between a pair of left and right main frames, and a seed case is provided in any of the plurality of feeding portions. And a seeding roll inserted into the lower part of the seed case, and by feeding seeds in the seed case with the seeding roll, seeds are dropped onto a nursery or the like for each feeding part (for example, multi-row sowing) , See Patent Document 1).

JP-A-5-49312

  In the above technique, when removing the feeding portion from the multi-row seeding machine, first, all the feeding portions are mounted in a row on the main frame via connecting members or the like, and fitted into the shaft hole of the seeding roll. The inserted common roll shaft was pulled out, and then each feeding portion was removed from the connecting member and the like, and maintenance such as seed collection and sowing roll replacement was performed.

  For this reason, when removing the feeding part, when the roll shaft is pulled out, the seeding roll that has lost its support also falls at the same time, and the seeds remaining in the seed case are removed from the opening where the seeding roll was present. Therefore, it is necessary to collect the seeds using a vacuum cleaner or the like, and there is a problem that workability is deteriorated due to labor and time. Furthermore, there is a problem that the roll shaft needs to be pulled out in a state where loads of a large number of feeding portions are applied to the roll shaft, and the work force is large due to excessive pulling force.

  On the contrary, when attaching the feeding part, the seed case with the seeding roll fitted to the lower part is connected while the common roll shaft is fitted into the shaft hole of each sowing roll between the pair of left and right main frames. The work of fixing to a member or the like was sequentially performed for each feeding portion.

  For this reason, it is necessary to repeat the attaching operation of the feeding unit in a narrow work space between the main frames in a state where the roll shaft gradually becomes heavier due to the load of the added feeding unit, and the work load is large. There was a problem.

The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.
That is, in claim 1, in a multi-row seeding machine for sowing a plurality of seeds at a time, a feeding part formed by attaching a sowing roll to a seed case and a plurality of the feeding parts connected in rows A feeding unit is integrally configured by a member and a common roll shaft that passes through the seeding roll in the axial direction, and forms both ends of the feeding unit and an outer frame of the multi-row seeding machine. An attachment / detachment structure that allows easy attachment / detachment of the feeding unit is provided between the main frame and the main frame.
According to a second aspect of the present invention, the attaching / detaching structure is fastened to an end portion of the connecting member on one side of the connecting member and can be locked to the main frame, and on the other side of the connecting member. A joint structure that connects the roll shaft to an input shaft to the roll shaft, and the joint structure has a reduced diameter end of the other shaft in the shaft center hole of one of the roll shaft and the input shaft. A groove portion that is grooved in the radial direction at the end face of the reduced diameter end portion is loosely engaged with a first joint structure in which the portion is loosely inserted and a pin horizontally mounted in the shaft hole. And a second joint structure.
According to a third aspect of the present invention, a bearing case is detachably provided on one side of the connecting member, and the bearing case has a boss portion that can pivotally support the roll shaft inside the main frame.
According to a fourth aspect of the present invention, the attaching / detaching structure is provided on one side of the connecting member, the support member being locked to the end of the connecting member and fitted to the main frame, and the other side of the connecting member. And a joint structure for connecting the roll shaft to the input shaft to the roll shaft, the main frame is provided with a notch recess opened upward, and the support body is fitted into the notch recess. The roll shaft is pivotally supported on the support.
According to a fifth aspect of the present invention, the support includes a boss portion that can pivotally support the roll shaft on the inner side of the main frame, and the boss portion is fitted into the notch recess.
According to a sixth aspect of the present invention, the joint structure is formed by inserting an end portion of the roll shaft into a shaft center hole of the input shaft through a one-way clutch type bearing.

Since this invention was comprised as mentioned above, there exists an effect shown below.
That is, according to the first aspect, all the feeding parts can be easily detached from the multi-row seeding machine as a part of the feeding part unit, and the work load is reduced. Furthermore, the seeding roll does not fall at the time of such removal, and the seeds remaining in the seed case are not scattered below the multi-row seeding machine, so that labor and time are not required and workability is improved. In addition, after the maintenance, all the feeding parts can be attached to the multi-row seeding machine as a feeding part unit, and the attaching work is repeated in a narrow work space and with the roll shaft gradually becoming heavier. This is not necessary and the workload is further reduced. In this way, seed collection and maintenance are facilitated.
According to a second aspect of the present invention, the support body is detached from the connecting member and the main frame to secure a work space for separating the feeding unit, and the first joint structure moves toward the work space side. The roll shaft can be pulled out from the input shaft and pulled up while tilting the feeding unit, and the feeding unit can be easily separated from the multi-row seeding machine, eliminating the need for complicated attachment and detachment and reducing the number of parts. Therefore, the manufacturing cost can be reduced and the maintainability can be improved. Furthermore, with the second joint structure, the rotational force of the input shaft can be reliably transmitted to the roll shaft, and sowing accuracy can be improved.
In Claim 3, By removing the said bearing case from a main frame, the work space for the separation | elimination operation | work of a feeding part unit can further be ensured between the edge part of the said roll axis | shaft, and a main frame, The part unit can be more easily separated from the multi-row seeder.
In Claim 4, after removing a support body from a notch recessed part and securing a large working space for the separation | separation operation | work of the said delivery part unit in the side of both members of a connection member and a roll axis | shaft, in this working space The roll shaft can be detached from the input shaft, and the feeding unit can be pulled up as it is. The feeding unit can be easily separated from the multi-row seeding machine, eliminating the need for a complicated attachment / detachment structure and reducing the number of parts. The manufacturing cost can be reduced and the maintainability can be improved. In addition, since the notch recess exposed after the support is removed from the main frame is opened upward, the roll shaft can be reliably prevented from interfering with the main frame when the feeding unit is pulled up. This can improve the workability of the separation work.
In claim 5, by removing the support from the notch recess, it is possible to further secure a work space for separating the feeding unit between the end portion of the roll shaft and the main frame, The feeding unit can be more easily separated from the multi-row seeder.
In Claim 6, between a roll axis | shaft and an input shaft can be connected with a simple structure, a complicated joint structure becomes unnecessary, and the reduction of the manufacturing cost by the number of parts reduction and the improvement of maintainability are aimed at. In addition, it is possible to prevent the roll shaft from interfering with the joint member or the like during the separating operation of the feeding unit, and the workability of the separating operation can be further enhanced. Furthermore, the clutch is turned “on” only when the input shaft rotates in the seed feeding direction of the roll shaft, and the roll shaft is set by setting the bearing so that rotational power is transmitted from the input shaft to the roll shaft. It is possible to prevent the seed from rotating in the non-feeding direction, and to prevent the seed from being damaged.

It is the whole perspective view from the left which shows the whole structure of the multi-row seeding machine in connection with this invention. Similarly, it is a partial perspective view from the right side. It is an assembly drawing of a feeding unit. It is an assembly drawing of a cropping member, a seed flowing member, and a soil covering member. It is an enlarged assembly view of a feeding unit. It is a perspective view of a feeding unit. It is a perspective view of the feeding unit with the bolt and knob screw removed. FIG. 5 is a perspective view of the feeding unit with the mounting stay and the bearing case removed. It is a top view of the bearing case which shows the support condition of the left roll shaft end part. FIG. 10A is a perspective view showing a joint structure of a right roll shaft end, FIG. 10A is a perspective view of a roll shaft end having a radial groove, and FIG. 10B is a roll shaft end having a radial groove. It is a perspective view of the input-shaft end part which has a part and a pin. FIG. 11A is a perspective view of the feeding unit placed on the work table, FIG. 11A is a perspective view of the feeding unit before the roll shaft is pulled out, and FIG. 11B is a feeding unit after the roll shaft is pulled out. FIG. It is an assembly drawing of the supply part unit which has the attachment / detachment structure of another form. It is a perspective view of the left sowing apparatus support part vicinity which shows the attachment or detachment structure of the left connection plate end part and roll shaft end part. It is a perspective view of the right seeding apparatus support part vicinity which shows the attachment or detachment structure of the right connection board edge part and roll shaft end part. It is a perspective view of a feeding unit. It is a perspective view of the feeding unit with the knob screw removed. It is a perspective view of the feeding unit with the mounting plate removed.

Hereinafter, embodiments of the present invention will be described in detail.
The direction indicated by the arrow F in FIG. 1 is the forward direction of the multi-row seeding machine 1, and the positions and directions of the members described below are based on this forward direction.

First, the overall configuration of the walking type multi-row seeding machine 1 according to the present invention will be described with reference to FIGS. 1, 2, and 5.
In the multi-row seeding machine 1, a pair of left and right main frames 3L and 3R are provided, and a front axle 4 of a front roller 6 is supported between front portions of the main frames 3L and 3R. Between the rear portions, the rear axle 5 of the pressure reducing roller 7 is supported. In addition, seeding device support plates 9 and 10 are respectively fixed to the front and rear substantially central portions of the main frames 3L and 3R, and the feeding unit 31 and the like according to the present invention are provided between the seeding device support plates 9 and 10, respectively. A seeding device 2 is provided.

  Further, on the main frames 3L and 3R, a pair of left and right stays 12 and 12 are erected between the rear axle 5 and the seeding device support plates 9 and 10, and at the upper ends of the stays 12 and 12, A frontal portal-type handle 11 is connected so as to be capable of pivoting back and forth. Handle height adjustment frames 13 and 13 are extended from the middle part of the handle 11 to the rear of the main frames 3L and 3R, and long holes 13a and 13a provided at the lower ends of the handle height adjustment frames 13 and 13, respectively. Bolts 22 and 22 projecting outward from the main frames 3L and 3R are locked to 13a.

  As a result, the bolts 22 and 22 can be loosened and the elongated holes 13a and 13a can be slid along the bolts 22 and 22, and the height of the handle 11 is increased by moving the handle height adjustment frames 13 and 13 up and down. I try to adjust it.

  A pair of left and right arms 15L and 15R are erected from the support portion of the front axle 4 on the front ends of the main frames 3L and 3R, and a battery base 16 is mounted on the arms 15L and 15R. The battery 14 is mounted on the battery base 16. The battery 14 is connected to a motor switch 20 provided at a substantially right and left central portion of the grip arm 11 a of the handle 11 via a signal line 17 and is built in the pressure reducing roller 7 via an electric wire 18. Connected to the traveling motor 21.

  As a result, when the motor switch 20 is operated while gripping the handle 11, electric power is supplied from the battery 14 to the traveling motor 21 by the signal from the motor switch 20, and the pressure reducing roller 7 is driven by the motor. 1 is able to run.

In addition, an interlocking device 23 for driving the seeding device 2 in conjunction with the rotation of the front roller 6 is disposed in the front half of the right main frame 3R.
The interlock device 23 includes a sprocket 24 fixed to the front axle 4 of the front roller 6, a sprocket 26 fixed to an input shaft 25 for inputting power to the seeding device 2, and the sprocket 26 and the sprocket. 24, and a chain case 28 that accommodates the sprocket 24, the sprocket 26, and the chain 27 and that is fixed to the front half of the right main frame 3R.

  Thereby, when the front roller 6 rotates with traveling, the rotational power of the front axle 4 is transmitted to the input shaft 25 through the sprocket 24, the chain 27, and the sprocket 26, and the seeding device 2 is automatically driven. Multi-row sowing is performed. The spot sowing interval at this time can be freely changed by changing the gear ratio of the sprockets 24 and 26, or by changing the circumferential interval of the concave portion 40a where seeds enter in the sowing roll 40 of the sowing apparatus 2 described in detail later. Can be adjusted.

  Each of the rollers 6 and 7 is covered with a sponge 30 on the outer peripheral surface thereof, thereby increasing the frictional resistance with the surface of the nursery bed and the like so as to prevent slipping and improve the driving force. I have to. Further, a scraper 35 for removing mud is attached behind the rollers 6 and 7.

Next, the configuration of the seeding device 2 will be described in detail with reference to FIGS.
As shown in FIG. 1 and FIG. 2, the sowing apparatus 2 includes a feeding unit 31, a rowing member 32, a seed flow member 33, and a soil covering member 34 according to the present invention.

  As shown in FIGS. 3 and 5, the feeding unit 31 includes a feeding unit 36 that feeds seeds, a connecting plate 37 that connects the feeding units 36 in a plurality of rows in the left-right direction, and the feeding unit 36. And a roll shaft 38 for driving the motor.

  The feeding portion 36 is formed by inserting a seeding roll 40 into the lower opening of the seed case 39 whose top and bottom are opened from the front diagonally lower side, and the seeding roll 40 has a shaft hole 40b at the center thereof and the seed hole 40b. It is arranged so as to be on the same axis as the through hole 39c drilled in the lower part of the case 39.

  In the seed case 39, seeds are stored in a hopper 39a provided in the upper part of the seed case 39, and a roll lip 39b is stretched inside the case below the hopper 39a so as not to spill the seeds. Furthermore, the concave portions 40a are formed on the outer peripheral surface of the sowing roll 40 at substantially equal intervals in the circumferential direction so that seeds enter the concave portions 40a. A fixed groove 39d is formed in the left and right direction at the lower end of the seed case 39, and a common fixed shaft 50 is screwed at both ends to the right and left seeding device support plates 9 and 10 in the fixed groove 39d. Is inserted.

  The connecting plate 37 includes a connecting portion 37a provided between the left and right main frames 3L and 3R, and left and right mounting portions 37b and 37c formed by bending both left and right ends of the connecting portion 37a forward. The A plurality of screw holes 37d are formed in the connecting portion 37a at substantially equal intervals in the left-right direction, and the front portion of the seed case 39 of each of the feeding portions 36 described above is formed by bolts 43 in the screw holes 37d. Fastened and fixed. A common lid 44 is attached to the upper portion of the connecting plate 37 by hinges 45 and 45 so as to be openable and closable so that the upper openings of all the seed cases 39, 39. .

  As described above, after the plurality of feeding portions 36 are fixed to the rear surface of the common connecting plate 37 and arranged in the left-right direction, all the through holes 39c, 39c,... And the shaft holes 40b, 40b,. The feeding unit 31 is integrally configured by passing the single roll shaft 38 through.

  A seeding roll 40 is fixed to the roll shaft 38 through the shaft holes 40b, 40b, and the right end of the roll shaft 38 is connected to the input shaft 25 from the interlocking device 23 later. It is connected via a joint structure 61 to be described in detail.

  Thereby, when the front roller 6 rotates and the rotational power of the front axle 4 is transmitted from the input shaft 25 to the roll shaft 38, the seeding roll 40 rotates together with the roll shaft 38, and the outer peripheral surface The seed in the recess 40a is continuously drawn out and falls onto the seed flow member 33. Note that a brush 42 is disposed in front of the roll lip 39b so that seeds that do not fit in the recess 40a are repelled by the brush 42.

  In addition, as shown in FIG. 4, in the grooving member 32, a number of grooving claws 32a are fixed to the lower portion thereof, and a pair of left and right fixing rods 32b and 32b project from the upper surface thereof. The fixing bars 32b and 32b are inserted from below into the longitudinal holes 46c and 46c of the inter-row fixtures 46 and 46, and are fixed by bolts 48a. Furthermore, the horizontal fixing holes 46a and 46b are formed with front and rear horizontal shaft holes 46a and 46b, respectively. The horizontal shaft holes 46a and 46b have front and rear intermediate fixing shafts 47a and 46b, respectively. 47b is inserted. Of these, the inter-row fixing shaft 47a is fixed by a bolt 48b, and both ends of the inter-row fixing shafts 47a and 47b are screwed and fixed to the left and right main frames 3L and 3R. As a result, the grooving member 32 is arranged at the front portion of the multi-row sowing machine 1 to support the grooving claws 32a, and the insertion length of the fixing rods 32b and 32b into the vertical axis holes 46c and 46c is increased. It is changed so that the height of the lower end of the composition claw 32a can be changed to adjust the composition depth.

  In the seed flow-down member 33, a number of sink plates 33a are fixed to the lower part of the sink arm 33b, and the sink arm 33b is disposed so as to receive a seed fed out from the feeding portion 36. The In addition, the left and right side plates 33c and 33d are screwed by screws 49 and 49 from the outside of the seeding device support plates 9 and 10, respectively. Thereby, the seed flow-down member 33 is arrange | positioned so that a seed can be guided under the feeding part 36 of the multi-row seeding machine 1.

  In the soil covering member 34, a number of soil covering rakes 34b suitable for the number of strips are fixed to the lower portion of the rake arm 34a, and left and right side plates 34c and 34c extend diagonally forward and upward from both ends of the rake arm 34a. The side plates 34c and 34c are provided with an upper hole 34d and a locking hole 34e in this order from the top.

  The fixed shaft 50 is inserted into the upper hole 34 d, and the soil covering member 34 is supported between the seeding device support plates 9 and 10 together with the seed case 39, and the fixed shaft 50 is centered. And tilted back and forth.

  A tip portion of a lower bent portion 51a of a protruding spring bar 51 is inserted into the locking hole 34e, and the tip portion is a long hole formed in an arc shape in side view by the seeding device support plates 9 and 10. 9a and 10a are locked by a locking pin 56. On the other hand, the upper end of the spring bar 51 is screwed into and inserted into spring receivers 52 fixed to the left and right main frames 3L and 3R, and a spring between the spring receiver 52 and the base of the lower bent portion 51a. A spring 55 is wound around the rod 51 in a compressed state.

  As a result, the soil covering member 34 is always urged downward about the fixed shaft 50 by the elastic force of the spring 55, and the locking position of the lower bent portion 51a with respect to the long holes 9a and 10a is changed. The insertion depth of the soil covering rake 34b into the soil can be adjusted.

  In the configuration as described above, when the multi-row seeding machine 1 travels, the front roller 6 rotates and the feeding unit 36 is driven by the rotational power of the front axle 4 so that the seed is fed from the feeding unit 36 and falls. Then, the seed guided in the sink plate 33a falls on the soil cultivated by the grouting claws 32a, and then the soil can be covered by the soil covering rake 34b.

Next, the attachment / detachment structure of the feeding unit 31 will be described with reference to FIGS.
First, the attachment / detachment structure of the connecting plate 37 constituting the feeding unit 31 will be described.
As shown in FIGS. 6 and 7, the right attachment portion 37 c of the connecting plate 37 is formed by a bolt 57 screwed into the hole 37 f of the attachment portion 37 c and the screw hole 10 b at the upper end of the seeding device support plate 10. It is fastened to the right seeding device support plate 10 so as to be detachable from the outside.

  On the other hand, the left attachment portion 37b is fastened to the attachment stay 53 so as to be detachable from the outside by a bolt 54 screwed into the hole 37e of the attachment portion 37b and the screw hole 53a at the upper end of the attachment stay 53. The mounting stay 53 includes a standing portion 53b having a screw hole 53a drilled at an upper end thereof, and a locking portion 53c having a concave shape when viewed from the front and opened inward below the standing portion 53b.

  Here, the left main frame 3L is U-shaped in cross-sectional view, and is a vertical plate-shaped main body 3La that is long in the front-rear direction, and a protruding portion that protrudes outward from the upper and lower edges of the main body 3La. The locking portion 53c of the mounting stay 53 is detachably locked from the outside to the overhanging portion 3Lb on the upper portion. The right main frame 3R is similarly composed of a vertical plate-like main body 3Ra extending in the front-rear direction, and overhangs 3Rb and 3Rc protruding outward from the upper and lower edges of the main body 3Ra. The

The attachment / detachment structure of the roll shaft 38 constituting the feeding unit 31 will be described.
As shown in FIGS. 6 and 9, the left end of the roll shaft 38 is rotatably supported by a bearing case 58 attached to the outer surface of the main body 3La of the left main frame 3L. In the bearing case 58, a cylindrical boss portion 58a including an inner boss portion 58b and an outer boss portion 58c is formed at a substantially central portion in a side view, and the inner boss portion 58b is formed as the main body portion 3La. Is inserted into a large-diameter boss hole 3Ld. Further, through holes 58d and 58e are drilled in front and rear of the boss portion 58a in the bearing case 58, and screw holes 3Le and 3Lf are also drilled in front and rear of the boss hole 3Ld in the main frame 3L.

  As a result, the inner boss portion 58b is fitted into the boss hole 3Ld, the bearing case 58 is positioned, the front knob screw 59 is screwed into the screw hole 3Le through the hole 58d, and the rear knob screw 60 is similarly inserted. Is screwed into the screw hole 3Lf through the through hole 58e, so that the bearing case 58 is screwed to the left main frame 3L so as to be detachable from the outside. The left end of the roll shaft 38 is rotatably supported by the inner boss portion 58b. The support position is set on the inner side of the inner side surface 3Lg of the main frame 3L, and the bearing case 58 is removed. A gap 65 is formed between the left end of the roll shaft 38 and the main frame 3L.

On the other hand, as shown in FIG. 10, the right end of the roll shaft 38 is detachably connected to the input shaft 25 via a joint structure 61.
In the joint structure 61, at the right end portion of the roll shaft 38, the large diameter portion 38a, which is the main body of the roll shaft 38, is reduced in diameter to form a small diameter portion 38b, and the end surface 38c of the small diameter portion 38b has a radial direction. A groove 38d is formed in the radial direction, and a stepped portion 38e is formed from the large diameter portion 38a to the small diameter portion 38b.

  On the other hand, at the left end portion of the input shaft 25 disposed to face the roll shaft 38, a shaft center hole 25a is formed on the shaft center, and the inner diameter of the shaft center hole 25a is a small diameter of the roll shaft 38. It is set to be slightly larger than the outer diameter of the portion 38b and smaller than the outer diameter of the large-diameter portion 38a, and the small-diameter portion 38b of the roll shaft 38 is input until the step portion 38e contacts the left end portion of the input shaft 25. The first joint structure 61a is configured so that the shaft 25 can be freely fitted and inserted into the shaft hole 25a.

  Further, a pin 25b is provided in the axial center hole 25a of the input shaft 25 in the radial direction, and the outer diameter of the pin 25b is set smaller than the size of the radial groove 38d. Until the abutment contacts the pin 25b of the input shaft 25, the radial groove 38d of the roll shaft 38 can be loosely engaged with the pin 25b of the input shaft 25, thereby forming the second joint structure 61b. At this time, in the second joint structure 61b, the radial groove 38d in which the pin 25b is loosely fitted is in the orthogonal direction with respect to the rotation direction of the pin 25b, so that the rotational force of the input shaft 25 is reliably applied to the roll shaft 38. Can be communicated to.

A procedure for detaching the feeding unit 31 having such an attachment / detachment structure of the connecting plate 37 and the roll shaft 38 will be described.
First, as shown in FIGS. 6 and 7, the bolt 54 that fastens the left mounting portion 37 b of the connecting plate 37 to the mounting stay 53 and the right mounting portion 37 c are fastened to the right seeding device support plate 10. The bolts 57 are loosened and removed, and the knob screws 59 and 60 that are screwing the bearing case 58 to the main frame 3L are loosened and removed.

  Subsequently, as shown in FIGS. 7, 8, and 9, the mounting stay 53 is tilted, the locking portion 53 c of the mounting stay 53 is disengaged from the overhanging portion 3 </ b> Lb of the left main frame 3 </ b> L, and the mounting stay is By removing 53 from the connecting plate 37 and the left main frame 3L, a working space for separating the feeding unit 31 can be secured on the left side of the connecting plate 37. In addition, the inner boss portion 58b of the boss portion 58a is extracted from the boss hole 3Ld, and the bearing case 58 is removed from the left main frame 3L, so that the gap 65 is secured as a work space on the left side of the roll shaft 38. Can do. In addition, while removing the mounting stay 53 and the bearing case 58 in this way, the lower end of the seed case 39 is fitted and supported by the fixed shaft 50, so that the feeding unit 31 falls or rotates back and forth. There is no.

  Thereafter, as shown in FIGS. 8 and 10, the feeding unit 31 is moved to the left as indicated by an arrow 63 in a state where the connecting plate 37 and the roll shaft 38 are gripped by hand, and the roll shaft The small-diameter portion 38 b of 38 is extracted from the axial hole 25 a of the input shaft 25. At this time, since the roll shaft 38 is loosely fitted to the input shaft 25 by the first joint structure 61a, the extraction force can be small. Subsequently, the tilting unit 31 is lifted upward as indicated by an arrow 64 while being tilted so that the left side becomes higher, and the feeding unit 31 is separated from the multi-row seeding machine 1. At this time, as described above, since a work space is secured on the left side of the feeding unit 31, particularly on the left side of the connecting plate 37, the feeding unit 36 and the roll shaft 38 constituting the feeding unit 31 during the separation work. Is not interfered with by surrounding members.

  As shown in FIG. 11, the separated feeding unit 31 is placed on the work table 62, and the knob screw 59 is screwed into the screw hole 38 f on the shaft center provided at the left end of the roll shaft 38. After gripping the knob screw 59, the roll shaft 38 is pulled out from the feeding portion 36 to the left. At this time, since the roll shaft 38 can be pulled out in a state where the load of the feeding portion 36 hardly acts, the pulling force can be small. Further, since the sowing roll 40 is placed on the work table 62, the sowing roll 40 does not fall even if the roll shaft 38 is pulled out.

  That is, in the multi-row seeding machine 1 for seeding a plurality of seeds at a time, a feeding part 36 formed by mounting the sowing roll 40 on the seed case 39 and a connecting member for connecting the feeding parts 36 in a plurality of rows. The connecting plate 37 and the common roll shaft 38 that passes through the seeding roll 40 in the axial direction rotate integrally with the feeding unit 31, both ends of the feeding unit 31, and the multiple Since the attachment / detachment structure for easy attachment / detachment of the feeding unit 31 is provided between the main frames 3L and 3R forming the outer frame of the row seeder 1, all the feeding units 36 are part of the feeding unit 31. Can be easily removed from the multi-row seeding machine 1, and the work load is reduced. Furthermore, the seeding roll 40 does not fall at the time of such removal, the seeds remaining in the seed case 39 are not scattered below the multi-row seeding machine 1, and workability is not required and time is not required. improves. In addition, after the maintenance, all the feeding units 36 can be collectively attached to the multi-row seeding machine 1 as the feeding unit 31, and the installation work can be performed in a narrow work space and the roll shaft 38 gradually becomes heavier. There is no need to repeat the process, and the workload is further reduced. In this way, seed collection and maintenance are facilitated.

  Further, the attachment / detachment structure is an attachment stay that is fastened to an end portion of the connection plate 37 on the left side that is one side of the connection plate 37 that is the connection member and is a support that can be locked to the main frame 3L. 53 and a joint structure 61 for connecting the roll shaft 38 to the input shaft 25 to the roll shaft 38 on the right side which is the other side of the connecting plate 37, and the joint structure 61 includes the roll shaft 38. A first joint structure 61a that loosely inserts a small diameter portion 38b that is a reduced diameter end portion of the roll shaft 38 that is the other shaft into the shaft center hole 25a of the input shaft 25 that is one of the input shafts 25; A second joint that loosely engages a radial groove 38d, which is a groove grooved in the radial direction at the end face 38c of the small diameter portion 38b, with a pin 25b that is horizontally mounted in the axial hole 25a. Since the structure 61b is provided, the mounting The tape 53 is removed from the connecting plate 37 and the main frame 3L to secure a working space for separating the feeding unit 31 and then rolled toward the working space by the first joint structure 61a. The shaft 38 can be extracted from the input shaft 25 and can be pulled up while tilting the feeding unit 31 as it is, and the feeding unit 31 can be easily separated from the multi-row seeding machine 1 and a complicated detachable structure is not required. It is possible to reduce the manufacturing cost and improve the maintainability by reducing the number. Further, the rotational force of the input shaft 25 can be reliably transmitted to the roll shaft 38 by the second joint structure 61b, and sowing accuracy can be improved.

  In addition, a bearing case 58 is detachably provided on the left side, which is one side of the connecting plate 37, and the bearing case 58 has a boss portion 58a capable of supporting the roll shaft 38 inside the main frame 3L. Therefore, by removing the bearing case 58 from the main frame 3L, a gap 65 is further secured as a work space for separating the feeding unit 31 between the end of the roll shaft 38 and the main frame 3L. The feeding unit 31 can be more easily separated from the multi-row seeder 1.

Next, another embodiment of the attachment / detachment structure of the feeding unit 31 will be described with reference to FIGS.
As shown in FIGS. 3 and 12, the attachment / detachment structure of another embodiment is provided with a mounting plate 66 made of a single member in place of the mounting stay 53 and the bearing case 58. 37 and the roll shaft 38A are simultaneously supported on the left main frame 67L. Further, when removing the feeding unit 31, the roll shaft 38A interferes with the main frame 67L by using the space after the attachment plate 66 is removed. This is intended to further improve the workability of the separation work.

  As shown in FIGS. 6 and 15, the pair of left and right main frames 67L and 67R used in the present detachable structure is different from the main frames 3L and 3R in that the left and right main frames 67L and 67R are provided for locking the mounting stay 53 and the like. The overhanging portions 3Lb, 3Lc, 3Rb, and 3Rc are not provided, and are formed in a plate shape on the left and right. Furthermore, seeding device support portions 67La, 67Ra, and 67Rb having the functions of the seeding device support plates 9 and 10 are integrally formed in substantially the same shape at the front and rear central portions of the main frames 67L and 67R, respectively. As a result, the multi-row seeding machine 1 is reduced in weight and the number of parts is reduced, thereby reducing manufacturing costs and improving maintainability.

First, the attachment / detachment configuration of the connecting plate 37 with respect to the main frames 67L and 67R will be described.
As shown in FIGS. 14 and 15, in the right main frame 67R, a support convex portion 67Rb is erected from the front portion of the seeding device support portion 67Ra, and the upper end of the support convex portion 67Rb has a horizontal direction. A support pin 69 having an axial center is provided, and a hole 37 f of the right mounting portion 37 c of the connecting plate 37 is fitted onto the support pin 69. Thereby, the right attachment part 37c of the connection plate 37 is locked to the right seeding device support part 67Ra so as to be detachable from the inside without using a fastening member such as a bolt.

  On the other hand, as shown in FIGS. 13 and 15, in the left main frame 67L, the mounting plate 66 is L-shaped in a side view, and is provided with a support pin 68 having an axial center in the left-right direction at the upper end. And a locking portion 66b extending rearwardly below the standing portion 66a. A hole 37e of the left mounting portion 37b of the connecting plate 37 is formed outside the support pin 68. I try to fit it. Accordingly, the left mounting portion 37b of the connecting plate 37 is also locked to the mounting plate 66 so as to be detachable from the inside without using a fastening member such as a bolt.

A configuration for attaching and detaching the roll shaft 38A will be described.
As shown in FIGS. 13, 15, and 17, the left end of the roll shaft 38 </ b> A is rotatably supported by the mounting plate 66 that locks the left mounting portion 37 b of the connecting plate 37.

  In the mounting plate 66, a cylindrical boss portion 66c composed of an inner boss portion 66d and an outer boss portion 66e is formed at the substantially central portion of the locking portion 66b in a side view, as in the bearing case 58. Of these, the base portion of the inner boss portion 66d is inserted into a notch recess portion 67Lb formed in the upper portion of the seeding device support portion 67La.

  Further, through holes 66f and 66g are drilled in front and rear of the boss portion 66c in the mounting plate 66, and screw holes 67Lc and 67Ld are drilled in front and rear of the notch recess 67Lb in the left main frame 67L. Has been.

  As a result, the inner boss 66d is inserted into the notch recess 67Lb, the mounting plate 66 is positioned, and the front knob screw 70 is screwed into the screw hole 67Lc through the through hole 66f. The rear knob screw 71 is screwed into the screw hole 67Ld through the through hole 66g, whereby the mounting plate 66 is screwed to the left main frame 67L so as to be detachable from the outside.

  In the mounting plate 66, a bearing 73 is inserted into the inner end of the inner boss portion 66d, and the left end of the roll shaft 38A can be rotated and detachably attached to the boss portion 66c via the bearing 73. It is supported. As in the case of the bearing case 58, the support position at this time is set on the inner side of the inner side surface 67Le of the main frame 67L. When the mounting plate 66 is removed, the left end of the roll shaft 38A and the main frame 67L A gap 72 is formed between the two.

On the other hand, as shown in FIGS. 12 and 14, the right end of the roll shaft 38 </ b> A is detachably connected to the input shaft 75 via a joint structure 74.
The input shaft 75 is formed of a large diameter portion 75a in the left half and a small diameter portion 75b in the right half of which the large diameter portion 75a is reduced in diameter. The small diameter portion 75b is an upper part of the seeding device support portion 67Ra. The right end of the small diameter portion 75b is fitted to the shaft center portion of the sprocket 26 shown in FIG. Further, screw holes 67Rc and 67Rd are formed before and after the input hole 67Re, and a bearing case 77 is fastened and fixed to the screw holes 67Rc and 67Rd by bolts 76. The small diameter portion is fixed to the bearing case 77. A midway part of 75 b is rotatably supported via a bearing 78.

  Thereby, when the front roller 6 shown in FIG. 2 rotates with traveling, the rotational power of the front axle 4 is transmitted to the input shaft 75 via the chain 27 and the sprocket 26.

  In such a large diameter portion 75a of the input shaft 75, a shaft center hole 75c is formed therein, and a one-way clutch type bearing 79 is inserted into the shaft center hole 75c. Then, the joint structure 74 is formed such that the small diameter portion 38Aa provided at the right end of the roll shaft 38A is inserted into the shaft hole 79a of the bearing 79 via the oil seal 80.

  Here, the bearing 79 is set as follows. That is, the input shaft 75 rotates in the same direction as the rotation direction of the roll shaft 38 </ b> A (hereinafter referred to as “seed feeding direction”) when the front roller 6 rotates and the seeds are normally fed out as the vehicle travels forward. Then, the bearing 79 becomes the clutch “ON”, and conversely, as the reverse roller travels, the front roller 6 rotates in the reverse direction, and when the input shaft 75 rotates in the direction opposite to the seed feeding direction, the bearing 79 becomes the clutch “OFF”. "

  As a result, only when the input shaft 75 rotates in the seed feeding direction from the input shaft 75 to the roll shaft 38A, the clutch becomes “ON” and the input shaft 75 and the roll shaft 38A are connected to transmit power. The roll shaft 38A is prevented from rotating in the direction opposite to the seed feeding direction.

A procedure for detaching the feeding unit 31 having the detachable configuration of the connecting plate 37 and the roll shaft 38A as described above will be described.
First, as shown in FIGS. 15 and 16, the knob screws 70 and 71 screwed to the left main frame 67L are loosened, and the mounting plate 66 is removed.

  Subsequently, as shown in FIGS. 13, 16, and 17, the inner boss portion 66d of the boss portion 66c is cut out to the left from the notch recess 67Lb, and the attachment plate 66 is simply removed from the left main frame 67L. The connecting plate 37 is removed from the main frame 67L, and a work space for separating the feeding unit 31 is secured to the left of the connecting plate 37. At the same time, the roll shaft 38A is also removed from the main frame 67L. Thus, a work space expanded by the gap 72 is secured to the left of the roll shaft 38A.

  Thereafter, as shown in FIGS. 14 and 17, the feeding unit 31 is moved to the left as indicated by an arrow 63 in a state where the connecting plate 37 and the roll shaft 38A are gripped by hand, and the roll shaft The small-diameter portion 38Aa of 38A is extracted from the shaft hole 79a of the bearing 79 inserted into the input shaft 75. At this time, since the roll shaft 38A and the input shaft 75 are connected by a simple configuration in which the roll shaft 38A is simply inserted and fitted into the shaft hole 79a, the joint structure 74 is not required to have a complicated joint structure. Sometimes, the roll shaft 38A does not interfere with the joint member or the like.

  Thereby, the feeding unit 31 is pulled upward as indicated by an arrow 64, and the feeding unit 31 is separated from the multi-row seeding machine 1. At this time, since a sufficient working space is secured on the left side of the feeding unit 31 as described above, the feeding unit 36 and the roll shaft 38A constituting the feeding unit 31 are interfered by surrounding members during the separation work. It will not be done.

  In particular, after the mounting plate 66 is removed from the left main frame 67L, the notch recess 67Lb opened upward appears, so that when the feeding unit 31 is pulled upward, the roll shaft 38A is removed from the main frame 67L. There is no interference.

  That is, another embodiment of the attachment / detachment structure is a support body that is locked to an end portion of the connection plate 37 and can be fitted to the main frame 67L on the left side that is one side of the connection plate 37 that is the connection member. A mounting plate 66 and a joint structure 74 for connecting the roll shaft 38A to the input shaft 75 to the roll shaft 38A on the right side, which is the other side of the connecting plate 37, are arranged above the main frame 67L. A notch recess 67Lb that is open is provided, and the mounting plate 66 is fitted into the notch recess 67Lb, and the roll shaft 38A is pivotally supported by the mounting plate 66. Therefore, the mounting plate 66 is removed from the notch recess 67Lb. A working space for separating the feeding unit 31 is enlarged to the side of both the members of the connecting plate 37 and the roll shaft 38A. After securing, the roll shaft 38A can be detached from the input shaft 75 toward the work space, and the feeding unit 31 can be pulled up as it is, and the feeding unit 31 can be easily separated from the multi-row seeding machine 1 and complicated. This eliminates the need for a detachable structure, thereby reducing the manufacturing cost due to the reduction in the number of components and improving the maintainability. Moreover, since the notch recess 67Lb exposed after the mounting plate 66 is removed from the main frame 67L is opened upward, the roll shaft 38A interferes with the main frame 67L when the feeding unit 31 is pulled up. Can be reliably prevented, and the workability of the separation work can be improved.

  Furthermore, the mounting plate 66 as the support includes a boss portion 66c that can pivotally support the roll shaft 38A on the inner side of the main frame 67L, and the boss portion 66c is fitted into the notch recess 67Lb. By removing the mounting plate 66 from the notch recess 67Lb, a working space for separating the feeding unit 31 can be further secured between the end of the roll shaft 38A and the main frame 67L. The unit 31 can be separated from the multi-row seeder 1 more easily.

  In addition, the joint structure 74 is formed by inserting a small-diameter portion 38Aa, which is an end portion of the roll shaft 38A, into the axial hole 75c of the input shaft 75 via a one-way clutch type bearing 79. With the configuration, the roll shaft 38A and the input shaft 75 can be connected to each other, a complicated joint structure is not required, the manufacturing cost can be reduced by reducing the number of parts, and the maintainability can be improved. It is possible to prevent the roll shaft 38 </ b> A from interfering with a joint member or the like during the separation work of the feeding unit 31, and the workability of the separation work can be further enhanced. Furthermore, the bearing 79 is set so that the clutch is “on” only when the input shaft 75 rotates in the seed feeding direction of the roll shaft 38A, and the rotational power is transmitted from the input shaft 75 to the roll shaft 38A. Thus, it is possible to prevent the roll shaft 38A from rotating in the non-feeding direction of the seed and to prevent the seed from being damaged.

  The present invention can be applied to all multi-row seeding machines that sow a plurality of seeds at a time.

1 Multi-row seeding machine 3L ・ 3R ・ 67L ・ 67R Main frame 25 ・ 75 Input shaft
25a / 75c shaft hole
25b pin
31 Feeding unit
36 Feeding part 37 Connecting plate (connecting member)
38 / 38A Roll shaft 38b Small diameter part (reduced diameter end part)
38c End face 38d Radial direction groove (groove part)
38Aa End of roll shaft 39 Seed case 40 Seeding roll 53 Mounting stay (support)
58 Bearing case 58a / 66c Boss part 61/74 Joint structure 61a First joint structure 61b Second joint structure 66 Mounting plate (support)
67Lb Notch recess
79 Bearing

Claims (6)

  In a multi-row seeding machine for sowing a plurality of seeds at a time, a feeding part formed by mounting a sowing roll on a seed case, a connecting member for connecting the feeding parts in a plurality of rows, and a shaft for the sowing roll The feeding unit is integrally configured by a common roll shaft that passes through and rotates in the direction, and is fed between both ends of the feeding unit and the main frame that forms the outer frame of the multi-row seeder. A multi-row seeding machine characterized in that an attachment / detachment structure is provided for easy attachment / detachment of the head unit.   The attachment / detachment structure includes a support body fastened to an end portion of the connection member on one side of the connection member and engageable with the main frame, and the roll shaft on the other side of the connection member. A joint structure connected to the input shaft to the shaft, and the joint structure is configured to loosely insert the reduced diameter end of the other shaft into the shaft center hole of one of the roll shaft and the input shaft. A first joint structure, and a second joint structure that loosely engages a groove grooved in the radial direction at the end face of the reduced diameter end portion with a pin horizontally mounted in the shaft hole. The multi-row seeder according to claim 1, further comprising:   3. The bearing according to claim 2, wherein a bearing case is detachably provided on one side of the connecting member, and the bearing case has a boss portion that can pivotally support the roll shaft inside the main frame. Multi-row seeding machine.   The attachment / detachment structure includes a support body that is locked to an end portion of the connection member on one side of the connection member and can be fitted to the main frame, and the roll shaft on the other side of the connection member. A coupling structure connected to the input shaft to the roll shaft, the main frame is provided with a notch recess opened upward, the support is fitted into the notch recess, and the support is The multi-row seeding machine according to claim 1, wherein a roll shaft is supported.   The multi-row seeding machine according to claim 4, wherein the support includes a boss portion that can pivotally support the roll shaft on the inner side of the main frame, and the boss portion is fitted into the notch recess. .   The multi-joint structure according to claim 4 or 5, wherein the joint structure is formed by inserting an end portion of the roll shaft into a shaft center hole of the input shaft through a one-way clutch type bearing. Sowing machine.

Images