JP2010166821A - Agricultural material-supplying apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an agricultural material-supplying apparatus in which a simple improvement is applied to a driving member-supporting form and which can expand a range for adjusting a supplying amount without enlarging the size of the driving member. <P>SOLUTION: The agricultural material-supplying apparatus includes a fertilizer dispensing portion 21 for supplying a stored fertilizer from a dispensing case 20 to a prescribed position, and is provided with a driving member 61 for driving the fertilizer dispensing portion 21, and the driving stroke of the output portion 61B of the driving member 61 is changed to set the amount of fertilizer supplied, of the fertilizer dispensing portion 21. the output portion 61B of the driving member 61 is linked to the fertilizer dispensing portion 21, a swinging support 68 is provided between the input portion 61A and output portion 61B of the driving member 61, and swinging support position-changing means A is provided to change the position of the swinging support 68 in the longitudinal direction of the driving member 61 to drive and swing the driving member 61. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an agricultural material supply apparatus such as a fertilizer for supplying fertilizers and chemicals as agricultural materials to an appropriate place such as a field, and a sowing apparatus for directly seeding seeds as agricultural materials.

As a seed farming material supply device, there is a fertilizing device mounted on a rice transplanter. In this fertilizer applicator, a crank drive arm (publication number: 49) provided at the rear end of the PTO shaft (publication number: 45) extending rearward from the mission case (publication number: 10); An operation arm (publication number: 47) as a drive member for driving a feed mechanism (publication number: 22) for feeding fertilizer mounted on the machine body is linked by a linkage rod (publication number: 48). It adopts a configuration to do.
Accordingly, the operation arm is driven and swung by the linkage rod, thereby driving the feeding mechanism and feeding the fertilizer.
Then, positioning concave portions (number in the publication: 74) are formed at a plurality of locations on the lower surface of the operation arm so that the linkage position between the operation arm and the linkage rod can be changed along the longitudinal direction of the operation arm. Therefore, the driving stroke of the operation arm is changed by changing the linkage position, and the feeding amount is changed and adjusted.

JP 2007-267615 A

With the above configuration, the feed amount can be changed and adjusted. However, in order to further expand the adjustment range, it is necessary to increase the length of the operating arm from the swing fulcrum.
However, in order to increase the length of the operation arm, it is necessary to increase the member strength and increase the size, but it is necessary to use an expensive material with excessive quality as the operation arm. There is a limit that can be taken to lengthen the length.
On the other hand, in order to change the drive stroke of the crank mechanism attached to the PTO shaft, the variable adjustment operation is difficult because the crank mechanism is located below the fuselage frame. It was difficult to adopt variable adjustment mechanism.

  An object of the present invention is to provide an agricultural material supply apparatus capable of expanding the adjustment range of the feeding amount without causing an increase in the size of the drive member by simply improving the support form of the drive member. In the point.

〔Constitution〕
The characteristic configuration of the invention according to claim 1 is an agricultural material supply apparatus including a supply mechanism that supplies the stored agricultural material from the storage unit to a predetermined position. The agricultural material supply device includes a drive member that drives the supply mechanism, The size of the agricultural material supply amount of the supply mechanism is set according to the magnitude of the drive stroke of the output portion, the output portion of the drive member is linked to the supply mechanism, and the input portion and the output portion of the drive member A swing fulcrum position changing means is provided to change the position of the swing fulcrum along the longitudinal direction of the drive member to drive and swing the drive member. The effects are as follows.

[Action]
When the swing fulcrum position of the drive member is changed by the swing fulcrum position changing means, the ratio of the input side link length from the input portion to the swing fulcrum of the drive member to the output side link length from the swing fulcrum to the output portion. Changes. As a result, the drive stroke of the output section relative to the stroke of the input section changes.
In addition, changing the swing fulcrum position not only changes the input side link length, but also changes the output side link length. Therefore, the range of the link ratio is set to the length of the swing arm as described in the background art. It can be made larger than that of changing only (corresponding to the input side link length), and the adjustment range of the drive stroke of the output portion of the drive member can be increased.

〔effect〕
In this way, the adjustment range of the drive stroke of the drive member can be increased without increasing the size of the drive member and changing the length, and the required feed adjustment of agricultural materials can be easily performed.

〔Constitution〕
The characteristic configuration of the invention according to claim 2 resides in that the swing fulcrum position changing means is configured so that the position of the swing fulcrum can be moved to a position in close proximity to the output portion. The effect is as follows.

[Function and effect]
Since the swing fulcrum position of the drive member can be positioned very close to the output part, the link length from the swing fulcrum to the output part is extremely short, and the drive stroke of the output part is nearly zero It becomes.
As a result, it is possible to reveal a state in which the feeding mechanism is not substantially driven without interrupting power transmission to the input unit, and the applicability of the feeding mechanism can be improved.

〔Constitution〕
According to a third aspect of the present invention, the rocking fulcrum position changing means includes a moving member that moves the position of the rocking fulcrum and an adjusting operation tool that drives the moving member. Is configured such that it can be removed by disconnecting from the moving member or can be folded and stored, and the operation and effect thereof are as follows.

[Function and effect]
Since the adjustment operation tool for operating the swing fulcrum position of the drive member is removed or foldable, when the work is carried out by feeding out agricultural materials, the adjustment operation tool can be removed by removing the adjustment operation tool. The adjustment operation tool is unlikely to get in the way and is easy to handle.

It is the whole riding type rice transplanter with a fertilizer application side view. It is a whole top view of riding type rice transplanter with a fertilizer application. It is a rear view which shows a fertilizer application apparatus. It is a side view which shows the power supply structure to a fertilizer supply part, and the rocking | fluctuation fulcrum position change means of a drive member. It is a side view which shows the rocking | fluctuation fulcrum position change means of a drive member. It is a front view which shows the linkage structure of a drive member and a 1st linkage rod. It is a partially notched front view which shows the linkage structure of a drive member and a 1st linkage rod. It is a vertical side view which shows the feeding axis | shaft, feeding roll, intermediate | middle boss | hub part, key member, etc. which are provided in the up-and-down feeding case and those flange junction parts. It is a vertical front view which shows the feeding axis | shaft, feeding roll, intermediate | middle boss | hub part, key member, etc. which are provided in the up-and-down feeding case and those flange junction parts. (A) The side view which shows the state which combined the upper and lower delivery case, (b) The side view which shows the state which isolate | separated the lower delivery case. It is a top view which shows the vertical side view of an upper extension case, and a lower extension case. It is a rear view which shows the power supply structure to the fertilizer supply part and the rocking | fluctuation fulcrum position change means of a drive member based on another Example. It is a side view in FIG. FIG. 14 is an enlarged vertical rear view of the swing fulcrum position changing means in FIG. 13.

[First Embodiment]
Hereinafter, an example of an embodiment of the present invention will be described with reference to the drawings.
As shown in FIG. 1, an engine 13 and a transmission case 14 are provided on the front side of a body frame 10 of a traveling machine body 1 having a pair of left and right front wheels 11 and a pair of left and right rear wheels 12 that can be steered. 1 is an example of a supply device in which a control unit 15 equipped with a steering handle or the like and a driver's seat 16 are provided at the center of the body 1, and fertilizer is supplied to the rear part of the body frame 10 constituting the traveling body 1 as agricultural material. A fertilizer applicator 2 is arranged.

A driving unit step 17 having a substantially flat step portion is provided on both the left and right sides of the engine 13, between the control unit 15 and the driving seat 16, and on the left and right sides of the driving seat 16. Further, a reserve seedling table 18 is disposed on the left and right sides opposite to the location where the engine 13 is disposed.
At the rear of the traveling machine body 1, a link mechanism 19 having a lift cylinder 19a is connected so as to be movable up and down, and the seedling planting device 4 is mounted on the link mechanism 19 and the fertilizer application device 2 is mounted. Is configured.

[Fertilizer]
The fertilizer applicator 2 includes a transparent resin feeding case 20 for storing fertilizer, and four fertilizer feeding sections 21 as supply mechanisms arranged below the feeding case 20. As shown in FIGS. 1, 3, and 4, the fertilizer feeding unit 21 is supported by a support frame 22 provided on the upper portion of the vehicle body frame 10 near the rear side of the driver seat 16 at the rear part of the traveling machine body 1. The fertilizer fed from the fertilizer feeding unit 21 is configured to be supplied to the field by a groover 45 as a supply unit attached to the seedling planting device 4 side through the fertilizer transport path by the air volume by the wind generating means. .

  The support frame 22 includes a pair of left and right blower support plates 22a erected on the pair of left and right main frames 10A of the body frame 10, a column 22b erected above the blower support plate 22a, and a left and right column 22b. It is comprised with the horizontally long frame 22c spanned to the upper end side. One end side of a link mechanism 19 for mounting the seedling planting device 4 so as to be movable up and down is connected to the rear end side of the blower support plate 22a.

As shown in FIG. 8 and FIG. 9, the fertilizer feeding part 21 has a feeding roll 23 in which a large number of recesses 23 a for fertilizer insertion are formed on the outer periphery along the circumferential direction, below the fertilizer feeding port 20 </ b> C of the feeding case 20. And it arrange | positions rotatably above the funnel part 20D.
In addition, the code | symbol 23b in a figure is a brush which slidably contacts with the surrounding surface of the supply roll 23, and acts by grinding.

  As a result, the fertilizer enters from the feeding case 20 into the recess 23a of the feeding roll 23, and the fertilizer is fed to the funnel portion 20D by the intermittent rotation of the feeding shaft 26. And the high voltage | pressure wind from the electric blower 30 of the wind raising means mentioned later is supplied to the funnel part 20D via the ventilation duct apparatus 31, and a fertilizer passes along the fertilizer conveyance pipe | tube 46 with the high voltage | pressure wind, and is made into the groove production machine 45. The fertilizer is fed quickly and fertilizer is fed into the grooves formed on the paddy surface by the grooving device 45 to perform the fertilization work.

  As shown in FIG. 8, a switching plate 28 is supported in a fertilizer discharge port 25 formed on the front side of the fertilizer feed portion 21 of the fertilizer feed port 20 </ b> C of the feed case 20 so as to be swingable around the horizontal axis. A discharge hose 29 extends downward from the lower side of the switching plate 28. During normal seedling planting work, the switching plate 28 is operated in the closed posture shown by the solid line in FIG. 8, and the fertilizer from the feeding case 20 is fed to the funnel portion 20D. When the normal seedling planting operation is completed, the switching plate 28 is brought into the open position with the drive of the electric blower 30 and the seedling planting device 4 (specifically, the drive of the PTO shaft 57) stopped. When operated, the fertilizer remaining in the feeding case 20 enters the discharge hose 29 and is discharged.

[Winding means]
Winding means for transporting the fertilizer fed from the fertilizer application apparatus 2 to the seedling planting apparatus 4 side by wind force is configured as follows.
As shown in FIGS. 1 and 3, an electric blower 30 supported by a pair of left and right blower support plates 22a and driven by an electric motor 30A, and an air duct that introduces outside air into the electric blower 30 and causes the conveying air to flow. Device 31. And the air duct apparatus 31 is connected to the inlet part 32 for introducing and supplying outside air to the electric blower 30 and the outlet pipe side of the electric blower 30, and wind generated by the electric blower 30 is supplied to each funnel part 20D. It is comprised with the pipe-shaped air supply part 33 for supplying.

As shown in FIGS. 2 and 3, the intake portion 32 has a proximal end connected to the vehicle body laterally outward intake port of the electric blower 30, near the lateral side portion of the engine 13 on the distal end side, and behind the muffler 9. It is arranged with the air inlet 32a positioned at a location, and sucks hot air around the engine 13 and exhaust heat of the muffler 9.
The air supply section 33 connected to the exhaust port side of the electric blower 30 is connected to the bifurcated branch connection pipe 34 whose downstream side is branched to the left and right, and the end of the branch connection pipe 34 so as to be disposed laterally to the vehicle body. A plurality of branch discharge pipes 36 for sending fertilizer to each fertilizer supply location of the seedling planting device 4 to be described later. Is provided.

[Seedling planting equipment]
As shown in FIG.1 and FIG.4, the seedling planting apparatus 4 is comprised by 6 row planting, and is supported by the right and left sides of the three planting transmission cases 40 and the planting transmission case 40 so that rotation drive is possible. The rotating case 41, a pair of planting claws 42 provided at both ends of the rotating case 41, three grounding floats 43, a seedling table 44, and the like.
Of the fertilizer supply path from the fertilizer application device 2 to the seedling planting device 4, the end portion leading to the seedling planting device 4 is positioned one by one near the side of the seedling planting location by each seedling planting claw 42. It is connected to each of a plurality of grooves 45 arranged and attached to the ground float 43.
Specifically, the fertilizer transport pipes 46 connected to the grooving device 45 on the seedling planting device 4 side are connected to a large number of branch discharge pipes 36 of the wind generating means.

  A divided structure of the feeding case 20 will be described. As shown in FIG. 10, the feeding case 20 is configured so that the upper feeding case 20 </ b> A and the lower feeding case 20 </ b> B can be divided on the basis of the axis Z of the feeding shaft 26. The structure for assembling the upper and lower feeding cases 20A and 20B is as follows.

  That is, as shown in FIGS. 10 and 11, a rectangular flange portion 20a is formed at the lower end position of the upper feeding case 20A, and the axis Z of the feeding shaft 26 in the flange portion 20a is sandwiched between both ends of one long side portion. A plate-like bracket portion 20b is provided. The bracket portion 20b is formed in a shape that bends downward, and is provided with a hollow engagement hole 20c. A frame frame is formed so as to surround the hollow engagement hole 20c, and a lower end receiving frame portion 20d is formed on the lower end portion of the frame frame for locking and mounting an engagement piece 20f described later.

On the other hand, as shown in FIGS. 10 and 11, a rectangular flange portion 20e is formed at the upper end position of the lower feeding case 20B, and the axis Z of the feeding shaft 26 in the flange portion 20e is sandwiched between both ends of one long side portion. A plate-like engagement piece 20f is projected. A concave mounting surface 20g that is recessed upward is formed on the lower surface of the engagement piece 20f, and the engagement state is stabilized when the engagement piece 20f is placed on the lower end receiving frame portion 20d. Such a mechanism is given.
A lock 20E that maintains the closed state of the upper and lower feeding cases 20A and 20B is swingably attached to the funnel portion 20D of the lower feeding case 20B. The locking device 20E maintains the locked state by engaging the lock engaging portion 20h with the flange portion 20a of the upper extension case 20A.

  In order to assemble the upper and lower feeding cases 20A and 20B with the above configuration, as shown in FIG. 10B, the engaging piece 20f of the lower feeding case 20B is engaged with the engaging hole of the bracket portion 20b of the upper feeding case 20A. By inserting it into 20c, the engaging piece 20f can be engaged with the flange portion 20d. As shown in FIG. 10A, the lower feeding case 20B is lifted and the flange portions 20a and 20e are overlapped. The lower feeding case 20B can be assembled to the upper feeding case 20A.

Conventionally, a connecting pin is provided at the swing fulcrum position of the lower feeding case 20B in order to open the lower feeding case 20B downward for maintenance while connecting the upper and lower feeding cases 20A and 20B.
In the case of adopting such a configuration, it is difficult to obtain durability as a connection pin, and it is necessary to remove the connection pin when removing the lower supply case 20B from the upper supply case 20A.
On the other hand, as described above, by constructing an engagement structure between the bracket portion 20b and the engagement piece 20f, it is not necessary to use a component that is easily damaged such as a connecting pin, and the lower feeding case 20B is formed. Also when removing from the upper feeding case 20A, it is only necessary to pull out the engaging piece 20f from the bracket portion 20b, and the attaching / detaching operation can be easily performed.

  Next, the drive selection structure of the feeding roll 23 equipped with a pair of left and right is described. As shown in FIGS. 4 and 6, the fertilizer feeding portion 21 is supported by penetrating a feeding shaft 26 parallel to the drive shaft 55 that receives power transmission from the PTO shaft 57 at a predetermined position below the funnel portion 20 </ b> D of the feeding case 20. It is provided.

As shown in FIGS. 6 and 9, the pay-out shaft 26 includes a large-diameter passive gear portion 26A that constitutes a gear mechanism that receives power transmission from the drive shaft 55, a cylindrical holding portion 26B that continues to the passive gear portion 26A, It is formed with a long shaft portion 26C. A hole is provided in the internal space from the passive gear portion 26A to the cylindrical holding portion 26B and the shaft-shaped portion 26C, and the hole portion is a large-diameter hole portion 26a formed in the passive gear portion 26A. The medium-diameter hole portion 26b provided in the cylindrical holding portion 26B and the small-diameter hole portion 26c provided in the shaft-like portion 26C are configured.
A screw hole 26d for screwing and fixing a set screw 27 is formed at the end opposite to the passive gear portion 26A.
A power transmission key member 74 is inserted and attached to the hole.

Next, the intermediate boss body 75 equipped with the feeding roll 23 and fitted on the feeding shaft 26 will be described. As shown in FIG. 9, the intermediate boss body 75 is a pair of left and right having the same specifications, and is installed in a butted state. The intermediate boss body 75 is composed of a large-diameter cylindrical portion 75A and a small-diameter cylindrical portion 75B. The intermediate boss body 75 located on the passive gear portion side internally fits the cylindrical holding portion 26B of the feeding shaft 26. A large-diameter holding hole 75a for holding and a small-diameter holding hole 75b for fitting and holding the shaft-like portion 26C of the feeding shaft 26 are continuously formed. In the intermediate boss body 75 located at the end opposite to the passive gear portion side, a small-diameter holding hole 75b for internally fitting and holding the shaft-like portion 26C of the feeding shaft 26 is formed.
The pair of intermediate boss bodies 75 are supported by boss portions 20F formed at the left and right ends of the upper and lower feeding cases 20A and 20B, and a seal 20G is mounted on the inner side from the support position.

  A key groove 75c is formed on the inner peripheral surface of the small diameter holding hole 75b at the abutting end of the pair of intermediate boss bodies 75 so as to enter the depth from the abutting end by a predetermined length. Further, a positioning spring ball mechanism 75d is provided on the inner peripheral surface of the small diameter holding hole 75b of the intermediate boss body 75 located on the passive gear portion side.

  The key member 74 will be described. As shown in FIG. 9, the key member 74 is a long rod-shaped member, and has a large-diameter disk-shaped knob 74A on the hand side, a rod-shaped support 74B on the tip side of the knob 74A, and a support. A semicircular positioning part 74C is provided on the further tip side of 74B, and an engaging part 74D for the key groove 75c is provided on the tip of the positioning part 74C. Three display portions 74a, 74b, and 74c for positioning are provided in the axial direction between the knob portion 74A and the support portion 74B. Corresponding to the display portions 74a, 74b, 74c, three engaging holes 74d, 74e, 74f are provided in the axial direction in the downward surface of the positioning portion 74C, and a spring ball mechanism is provided in the engaging holes 74d, 74e, 74f. It is configured to engage a 75d ball.

  The small-diameter cylindrical portion 75B of the intermediate boss body 75 is fitted into each of the support holes 23A of the feeding roll 23 configured as described above, and the feeding roll 23 and the intermediate boss body 75 are integrated with each other. Assemble in a rotatable manner. The large-diameter cylindrical portion 75A of the intermediate boss body 75 is inserted and placed on the boss portion 20F of the feeding case 20 that adopts a vertically divided structure as will be described later. The key member 74 is inserted into the large diameter holding hole 75a and the small diameter holding hole 75b of the pair of intermediate boss bodies 75. With the key member 74 inserted, the engaging portion 74D engages with the key groove 75c of the intermediate boss body 75, and the positioning portion 74C is positioned at a position where it can engage with the spring ball mechanism 75d.

  The plug member 76 is fitted into the opening portion of the large-diameter cylindrical portion 75A of the intermediate boss body 75 at the opposite end of the feed shaft 26 from the passive gear side in a state where the feed shaft 26 is housed in a predetermined position on the intermediate boss body 75. The stopper member 76 and the feeding shaft 26 are fastened and fixed with a set screw 27, and the feeding shaft 26 is secured to the intermediate boss 75.

A method for operating the key member 74 will be described. As shown in FIG. 9, the pair of intermediate boss bodies 75 are arranged in a state where the end portions where the key grooves 75 c are formed are attached to each other in the state where they are mounted in the feeding case 20. The engaging portion 74D of the member 74 is engaged.
Therefore, the display portion 74c provided farthest from the knob portion 74A is aligned with the position corresponding to the end portion of the passive gear portion 26A, and the engaging portion 74D is moved to the key groove 75c of the intermediate boss body 75 on the passive gear side. In the case where the power is transmitted only through the passive gear 26A, the power transmitted to the feed shaft 26 via the passive gear 26A is fed to the feed gear roll via the key member 74 and the passive gear side intermediate boss body 75. 23 only. In this case, the ball of the spring ball mechanism 75d is engaged with the engagement hole 74f, and the positioning of the key member 74 is maintained.

  Holding the knob 74A of the key member 74 and pushing it in one step, as shown in FIG. 9, the intermediate display portion 74b is aligned with the position corresponding to the end of the passive gear portion 26A, and the engaging portion 74D is placed in the middle. When engaged with the key groove 75 c of the boss body 75, the power transmitted to the feeding shaft 26 via the passive gear portion 26 </ b> A is transferred to both feeding rolls 23 via the key member 74 and both intermediate boss bodies 75. Communicated. In this case, the ball of the spring ball mechanism 75d is engaged with the engagement hole 74e, and the positioning of the key member 74 is maintained.

  Hold the knob 74A of the key member 74 and push it one step further, align the display part 74a provided at the position closest to the knob 74A with the position corresponding to the end of the passive gear 26A, and set the engaging part 74D. When engaged only with the key groove 75c of the intermediate boss body 75 located on the opposite side to the passive gear portion 26A, the power transmitted to the feeding shaft 26 via the passive gear portion 26A is the key member 74, It is transmitted to the feeding roll 23 located on the opposite side to the passive gear portion 26A via the intermediate boss body 75 located on the opposite side to the passive gear portion 26A. In this case, the ball of the spring ball mechanism 75d is engaged with the engagement hole 74d, and the positioning of the key member 74 is maintained.

  As described above, by inserting / removing the key member 74 to / from the intermediate boss body 75, both the state in which only one of the feeding rolls 23 is driven to feed the fertilizer in a limited manner and the feeding roll 23 are both supplied. It was possible to configure a switching mechanism that can switch to a state in which the farm surface to which the fertilizer is applied by driving is widely expanded and fed out.

  Conventionally, in order to adjust the feeding amount, a ribbon-shaped shutter is provided to individually cover the recesses 23a for entering fertilizer, and a part or front of the recess 23a for entering fertilizer is closed to prevent fertilizer input And the structure which adjusts the supply of the fertilizer to the field surface was taken. Then, by pulling out the shutter from the feeding case 20 in the closed state, the feeding switching mechanism is configured to open the recess 23a for entering the fertilizer, to input the fertilizer and feed it to the field.

The following problems have been presented for the configuration using the shutter. That is, since the feeding roll 23 is maintained in the driving state, there is a possibility that the feeding of the fertilizer cannot be stopped immediately even when the shutter is closed.
In addition, since it is necessary to insert and remove the shutter while it is filled with fertilizer, the operation of inserting and removing the shutter is not easy, and smooth operability cannot be secured.

On the other hand, since the amount of feeding is adjusted using the key member 74, when the key member 74 is switched, the feeding is stopped immediately. In addition, since the key member 74 is mounted in the shaft of the feeding shaft 26, it is possible to perform the withdrawal operation without receiving the load of the stored fertilizer, and the operation can be easily performed.
Since no shutter is required, the number of parts can be reduced.

The power transmission structure to the fertilizer supply part 21 is as follows. As shown in FIG. 3 to FIG. 5, from the PTO shaft 57 extended rearward so as to transmit power from the mission case 14 to the seedling planting device 4, receiving the rotational motion of the rotary arm 58 that extracts power, A first linkage rod 59 linked to the eccentric position of the rotary arm 58 is provided to move up and down. A channel-shaped drive member 61 that swings the balance around the lateral fulcrum X is provided, and the upper end of the first linkage rod 59 is connected to an input portion 61A formed at one end of the drive member 61. The second linkage rod 62 extends upward from the output portion 61B on the opposite side across the lateral fulcrum X of the drive member 61 and is linked to the input arm 60A of the one-way clutch 60. The power converted into the rotational motion by the one-way clutch 60 is transmitted from the drive shaft 55 to the feed shaft 26 via the gear mechanism.

  As shown in FIGS. 6 and 7, the input portion 61 </ b> A of the driving member 61 is fitted with a laterally connecting pin 69 that penetrates the pair of side plate portions 61 </ b> C of the driving member 61, and a channel shape on the lower surface of the connecting pin 69 The upper boss portion 59 </ b> A of the first linkage rod 59 is externally fitted to the connecting pin 70 </ b> A that is installed across the pair of side plate portions of the bracket 70.

As shown in FIGS. 4 and 5, left and right support frames 66A and 66B are extended downward from the left and right ends of the horizontally long frame 22c that supports the fertilizer feeding portion 21 in the support frame 22, and the right support frame 66B. A positioning rod 73 is provided across the lower end portion 66b of the drive member 61 and the connecting pin 69 penetratingly supported by the input portion 61A of the drive member 61.
That is, mounting boss portions 73A and 73B are formed at both ends of the positioning rod 73, and one mounting boss portion 73A is externally fitted to the connecting pin 69 provided on the input portion 61A of the drive member 61, and the other mounting boss portion 73A is attached. The boss portion 73B is externally fitted to the mounting pin 66c of the lower end portion 66b of the right support frame 66B, and the positioning position of the positioning rod 73 with the first linkage rod 59 of the drive member 61 is not changed.

Next, the swing fulcrum position changing means A will be described. As shown in FIGS. 4 and 6, the swing fulcrum position changing means A adjusts the position of the swing fulcrum of the drive member 61 that swings the balance.
A feed shaft 63 having a thread groove 63A, a reciprocating member 64 that reciprocates along the axial direction of the feed shaft 63, and a small-diameter portion 63B extending from the right support frame 66B of the feed shaft 63 are detachable. It is comprised with the adjustment operation tool 65 with which it mounts | wears.

  The feed shaft 63 is installed over the left and right support frames 66A and 66B extending downward from the left and right ends of the horizontally long frame 22c, and is held by the lower end boss portions 66a and 66b of the left and right support frames 66A and 66B. The bearing 67 is rotatably supported around its own axis Y.

  The reciprocating member 64 includes a cylindrical holder portion 64A externally fitted to the feed shaft 63 and a channel-like suspension member 64B extending downward from the holder portion 64A. The suspension member 64 </ b> B forms a pair of lower end plate parts 64 a that are held at regular intervals on the left and right sides, and the lower end plate parts 64 a are externally fitted over the left and right side surfaces of the drive member 61.

As shown in FIGS. 4 and 7, a long hole 61a is formed in the pair of side plate portions 61C of the drive member 61, respectively, along the longitudinal direction of the side plate portion 61C, and suspended through the long holes 61a. A connecting pin 68 extending through the lower end plate portion 64a of the lowering member 64B is inserted. A bearing 68 </ b> A is externally fitted to the connecting pin 68, and the bearing 68 </ b> A is in sliding contact with the ceiling surface forming the internal space of the drive member 61, so that the reciprocating member 64 is smoothly moved.
The connecting pin 68 constitutes the swing fulcrum of the drive member 61.

As shown in FIGS. 4 and 6, an angled guide frame 71 is cantilevered from the right side surface of the right support frame 66B of the left and right support frames 66A and 66B that support the feed shaft 63 toward the right side. In addition to being erected, a guide hole 71 </ b> A is formed in the guide frame 71 along the axis Y direction of the feed shaft 63.
On the other hand, the guide rod 72 that engages with the guide hole 71A and guides the reciprocating member 64 extends from the state engaged with the guide hole 71A to the reciprocating member 64 and is connected and fixed to the reciprocating member 64. .

With the configuration as described above, the driving member 61 is suspended and supported so as to be able to swing the balance around the axis X of the connecting pin 68. When the adjusting operation tool 65 is rotated, the feed shaft 63 rotates around its own axis Y, and the reciprocating member 64 is moved along the axis Y of the feed shaft 63. The reciprocating member 64 is guided to move along the axis X by the guide rod 72. As a result, the fulcrum position where the driving member 61 swings the balance can be moved. If it does so, the link ratio which concerns on the balance swing of the drive member 61 will change, and the drive stroke of the output part 61B of the drive member 61 will change.

That is, when the position of the reciprocating member 64 is located at the end of the long hole 61a of the drive member 61 on the first linkage rod 59 side, the connection position from the fulcrum position (axis X) to the first linkage rod 59. The link ratio of the link length L2 from the fulcrum position (axial center X) to the connection position with the second linkage rod 62 with respect to the link length L1 is approximately 1.
From this state, the closer the position of the reciprocating member 64 is to the second linkage rod 62 side, the longer the link length L1 and the shorter the link length L2, and the link ratio gradually approaches zero.

When the position of the reciprocating member 64 is located at the end of the long hole 61a of the drive member 61 on the second linkage rod 62 side, the link length L1 is long and the link length L2 is almost zero. Therefore, the link ratio is substantially zero.
Thereby, the drive stroke in the output part 61B of the drive member 61 becomes substantially zero, and the fertilizer is not paid out.

  As described above, since the configuration using the feed shaft 63 is adopted to change the fulcrum position of the drive member 61, the fulcrum can be moved more finely than the pitch of the screw groove 63A by rotating the feed shaft 63. Compared with the case where the fulcrum position is directly slid with the operation tool, fine adjustment is possible, and the reciprocating member 64 is engaged with the screw groove 63A, so that the self-locking is applied. It is possible to fix in the adjustment position without introducing the lock mechanism.

As shown in FIGS. 3 and 5, the adjustment operation tool 65 is detachably attached to the small diameter portion 63B of the feed shaft 63 by a wing nut 63a, and does not get in the way by being removed during normal planting work. And can.
Although not shown, for example, the adjustment operation tool 65 itself may be folded at the position of the arm portion connected to the small diameter portion 63B. For example, the adjustment operation tool 65 may be fertilized by folding the small diameter portion 63B. It may be configured so that it can be folded close to the device 2.
Since the adjustment operating tool 65 is attached to the narrow diameter portion 63B extending to the opposite side of the feeding shaft 21 with respect to the first linkage rod 59 in the feed shaft 63, concentration of the equipment configuration can be avoided and operation can be avoided. Since the adjustment operation tool 65 can be installed in the vicinity of the seat 16, the adjustment operation of the adjustment operation tool 65 can be performed without getting off the driver's seat 16.

[Second Embodiment]
The structure different from 1st Embodiment of the power transmission structure to the fertilizer supply part 21 is demonstrated. As shown in FIGS. 12 and 14, from the PTO shaft 57 extended rearward so as to transmit power from the mission case 14 to the seedling planting device 4, the rotary arm 58 that receives the rotational motion receives the rotational motion, A first linkage rod 59 linked to the eccentric position of the rotary arm 58 is provided to move up and down.

As shown in FIG. 13, in the vicinity of the upper end of the first linkage rod 59, a laterally extending linkage shaft 85 is installed, and the upper ends of the receiving arm 85 </ b> A provided on the linkage shaft 85 and the first linkage rod 59 are Are linked. The linkage shaft 85 extends to the vicinity of the right end of the fertilizer applicator 2, and a drive arm 85B is attached to the right end position of the linkage shaft 85 itself. An interlocking arm 86 in an up / down posture is linked to the tip of the driving arm 85B, and the upper end of the interlocking arm 86 is connected to an input portion 61A of a channel-like driving member 61 that swings around a lateral fulcrum X. is there.
A tip end portion of a positioning arm 88 extending from the fixed side is connected to the input portion 61A of the driving member 61. With the positioning arm 88, regardless of the movement of the reciprocating member 64, the driving member 61 is moved. The movement is restricted so that the reference state of the swing fulcrum adjustment of the drive member 61 does not change.

A second linkage rod 62 extends downward from the output portion 61B at the opposite end across the lateral fulcrum X of the drive member 61 and is linked to the input arm 60A of the one-way clutch 60. The power converted into the rotational motion by the one-way clutch 60 is transmitted from the drive shaft 55 to the feed shaft 26 via the gear mechanism.

Next, the swing fulcrum position changing means A will be described with a structure different from that of the first embodiment.
As shown in FIGS. 13 and 14, the swing fulcrum position changing means A holds the screw shaft 80 having the male screw portion 80A and the nut member screwed into the male screw portion 80A, and the axis of the screw shaft 80. A reciprocating member 64 that reciprocates along the direction and an adjusting operation tool 65 that is detachably attached to the small diameter portion 80B of the screw shaft 80 are configured.

  A mounting structure of the screw shaft 80 will be described. A receiving frame 82 having a plate shape is provided inside a mounting box 84 that is installed in parallel with the axis of the screw shaft 80, and the front and rear support brackets are provided with a flange portion standing sideways at the front and rear ends of the receiving frame 82. 82A and 82B, the screw shaft 80 is rotatably supported around its own axis Y through a bearing 83 across boss portions 82a and 82b provided on the front and rear support brackets 82A and 82B. .

  The reciprocating member 64 includes a cylindrical holder portion 64A externally fitted to the screw shaft 80 and a channel-like suspension member 64B extending downward from the holder portion 64A. The suspending member 64B forms a pair of lower end plate portions 64a that maintain a constant interval on the left and right sides, and is externally fitted so that the drive member 61 is sandwiched between the lower end plate portions 64a.

  As shown in FIGS. 13 and 14, a long hole 61a along the longitudinal direction is formed in the side plate portion of the drive member 61, and extends through both the lower end plate portions 64a of the suspension member 64B through the long hole 61a. The connecting pin 68 is inserted. The connecting pin 68 constitutes the swing fulcrum of the drive member 61.

  A display plate 87 is attached to the lateral side of the holder portion 64, and an upper end portion of the display plate 87 is projected upward from the upper surface of the attachment box 84. On the upper surface of the mounting box 84, an indicator for displaying the feed amount of fertilizer or the like is provided, and the indicator is indicated by a guide plate 87 that moves by adjusting the fulcrum position of the drive member 61.

As shown in FIGS. 1 and 13, the adjustment operating tool 65 is screwed and fixed to the shaft end of the screw shaft 80, but is easy to operate because it is provided at the height position of the backrest portion of the driver seat 16. It is installed at the height.
In this case, although not shown, the adjustment operation tool 65 may be configured to be removable from the screw shaft 80 by hand, and the adjustment operation tool 65 is folded close to the fertilizer device 2 so that the screw shaft 80 can be folded. You may comprise so that accommodation is possible.

  With the above configuration, when the adjustment operating tool 65 is rotated, the screw shaft 80 rotates around its own axis, and the reciprocating member 64 is driven and moved along the screw shaft 80. Accordingly, as described above, the fulcrum position of the drive member 61 is changed, the link ratio of the drive member 61 is changed, and the feeding amount can be adjusted.

[Other Embodiments]
(1) The fertilizer feed amount is adjusted by rotating the feed shaft 63 and the screw shaft 80 in order to change the stroke of the output portion 40B of the drive member 40, but the feed shaft 63 is not used. Alternatively, the reciprocating member 64 may be directly slid and moved.
(2) The fertilizer feed amount is adjusted by artificially rotating the feed shaft 63 and the screw shaft 80 in order to change the stroke of the output portion 40B of the drive member 40. A configuration may be adopted in which the reciprocating member 64 is slidably moved by being rotationally driven by a drive motor. No artificial adjustment operation tool is required.
(3) The fertilizer feed amount is adjusted by manually rotating the feed shaft 63 and the screw shaft 80 in order to change the stroke of the output portion 40B of the drive member 40. A configuration may be adopted in which the control unit 15 is positioned below the boarding step and only the second linkage rod 62 is raised above the step.
(4) The adjusting operation tool 65 may be not only a handle type but also a foot pedal type.

The agricultural material supply apparatus according to the present invention can be applied not only to the fertilizer apparatus mounted on the above-described riding type rice transplanter but also to the following apparatus.
(B) A direct sowing apparatus that applies seed pods directly to the field surface may be used.
(B) A liquid supply device for applying liquid fertilizer may be used.
(C) A medicine spraying device may be used.
(2) It may be a seed vat feeding device used for a seedling raising device.

20 Feeding case (reservoir)
21 Fertilizer feed section (supply mechanism)
61 drive member 61A input unit 61B output unit 64 reciprocating member (moving member)
65 Adjustment operation tool 68 Connecting pin (swinging fulcrum)
A Swing fulcrum position change means

Claims (3)

An agricultural material supply device including a supply mechanism for supplying stored agricultural material from a storage unit to a predetermined position,
A drive member for driving the supply mechanism is provided, and configured to set the magnitude of the agricultural material supply amount of the supply mechanism according to the drive stroke of the output portion of the drive member, and the output portion of the drive member is the supply Linked to the mechanism, a swing fulcrum is provided between the input part and the output part of the drive member, and the position of the swing fulcrum is changed along the longitudinal direction of the drive member to drive the drive member. Agricultural material supply device provided with swing fulcrum position changing means for movement.   2. The agricultural material supply apparatus according to claim 1, wherein the swing fulcrum position changing means is configured to be movable to a position where the position of the swing fulcrum is in close proximity to the output unit.   The swing fulcrum position changing means includes a moving member that moves the position of the swing fulcrum and an adjustment operation tool that drives the movement member, and the adjustment operation tool is removed by disconnecting from the movement member. The agricultural material supply apparatus according to claim 1, wherein the agricultural material supply apparatus is configured to be capable of being folded or stored.

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