JP2018126166A - Transplanter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a transplanter suppressed in noise without hooking seedlings.SOLUTION: A transplanter includes: planting tools 11, 1011 in which supplied transplantation objects are housed, and the lower part of which can be opened or closed in the transverse direction of the machine body of the transplanter; an oscillation link mechanism 310 vertically oscillating the planting tools 11, 1011; and a planting tool opening/closing mechanism opening or closing the lower parts of the planting tools 11, 1011. Notched parts 1200F, 1200B are formed at either one or both of the front or/and the rear of mutually abutted end surface parts of double-split parts on the planting tools 11, 1011. A plate-like elastic member covering the notched parts 1200F, 1200B when the double-split parts close, is mounted on the insides of the planting tools 11, 1011. The transplantation objects housed in the planting tools 11, 1011 are held via the plate-like elastic member.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a transplanter for seedlings, seed pods and the like, and belongs to the technical field of agricultural machinery.

  2. Description of the Related Art Conventionally, as a transplanter, there is known a transplanter configured to include a seedling supply device and a seedling planting device for planting a seedling in a farm field (see, for example, Patent Document 1).

  In the seedling planting device of the conventional transplanter described above, a pair of left and right seedling planting bodies that can be opened and closed in the left-right direction for accommodating seedlings supplied from the seedling feeding device and planting them in a farm are formed in a bowl shape. Has been. And when a pair of right and left seedling planting bodies close, the noise which generate | occur | produces when a seedling planting body is closed is reduced by inserting a rod-shaped sealing regulating member from the outside of the seedling planting body.

JP 2005-102568 A

  However, in the conventional seedling transplanter, the supplied seedling may be caught in the gap between the tip of the rod-shaped sealing regulating member inserted into the seedling planting body and the seedling planting body, and the seedling may be damaged. It was.

  An object of this invention is to provide the transplant machine which can suppress a noise, without catching a seedling in view of the subject of such a conventional transplant machine.

  According to the first aspect of the present invention, there is provided a planting tool (11, 1011) in which the implant (22) to be supplied is housed and whose lower part can be opened and closed in the left-right direction of the machine body, and the planting tool (11, 1011). ) And a planting tool opening / closing mechanism (322, 340, 350, 1014, 1015L, 1015R) for opening and closing the lower part of the planting tool (11, 1011). The transplanter (11, 1011) is provided with a notch (1200F, 1200B) on one or both of the front and back of the end face portions of the two divided portions that are butted against each other. Then, a plate-like elastic member that covers the notch (1200F, 1200B) when the two divided parts are closed is provided inside the planting tool (11, 1011), and the planting tool (11, 1011) is provided. ) Implant contained therein (22) is an implantable device, characterized in that it is held through the plate-like elastic member.

  In the invention of claim 2, the planting tool (11, 1011) includes a left hopper portion (1011L) and a right hopper portion (1011R), and the notch portion (1200F, 1200B) includes the left hopper portion. (1011L) and the right hopper part (1011R) are formed on the front and rear end face parts, respectively, and the plate-like elastic members are respectively provided on the front side and the rear side of the planting tool (11, 1011). The transplanter according to claim 1, wherein the transplanter is provided.

  In the invention of claim 3, screw holes are respectively formed in the left hopper portion (1011L) and the right hopper portion (1011R), and bolts (1240L, 1240R) are inserted into the screw holes so as to be able to advance and retract, and the bolts (1240L, The transplanter according to claim 2, wherein the distal end of 1240R) is brought into contact with the back side of the plate-like elastic member.

  The invention of claim 4 is provided with a scraper device (1500) for bringing a scraper (1511) into contact with the inner surface of the planting tool (11, 1011), and the scraper (1511) of the planting tool (11, 1011). 4. The transplanter according to claim 1, wherein the implanter moves into the planting tool (11, 1011) while pushing away the plate-like elastic member when inserted into the plant. is there.

  Further, the first related invention related to the inventions according to the first to fourth aspects of the present invention contains the supplied implant (22) inside, and the lower part is two in the lateral direction of the body. A planting tool (11, 1011) that can be opened and closed separately, a swing link mechanism (310) that swings the planting tool (11, 1011) in the vertical direction, and the planting tool (11, 1011) The planting tool opening / closing mechanism (322, 340, 350, 1014, 1015L, 1015R) for opening and closing the lower part of the planting device is provided, and the planting tool (11, 1011) is abutted against each other in two parts. A plate-like elastic member that forms a notch (1200F, 1200B) on either the front or back of the end face, or both, and covers the notch (1200F, 1200B) when the two parts are closed The plate Elastic member is a transplantation machine, characterized in that it is arranged in an inclined position towards the longitudinal center of the in side view the planting device (11,1011).

  The second related invention related to the first to fourth inventions and the first related invention is characterized in that a concave portion (1210BU) is formed at the upper edge of the plate-like elastic member. The transplanter according to claim 1.

  Further, according to a third related invention related to the first to fourth inventions described above and the first or second related invention, the planting tool (11, 1011) includes a swing link mechanism (310). In the loop-like operation locus formed by the above, the implant (22) is implanted at or near the bottom dead center based on the operation of the planting tool opening / closing mechanism (322, 340, 350, 1014, 1015L, 1015R). The top dead center or the vicinity of the top dead center that receives the transplant (22) is opened with a degree smaller than the degree of opening, and the bottom dead center or the bottom dead center is opened from the stop position. The implant (22) is held via the plate-like elastic member by closing in the middle of descending to the vicinity of the dead center and closing in the middle of the planting tool (11, 1011) descending. Transplanter .

  According to the first aspect of the present invention, since the notch portion (1200F, 1200B) is formed, when the planting tool (1011) is closed, the contact range of the end surface portion is reduced, so that the contact sound is suppressed.

  In addition, by providing the plate-like elastic member, the transplant (22) can be prevented from being caught in the notch (1200F, 1200B), so that the seedling planting accuracy is improved.

  Further, the transplant (22) is prevented from dropping from the notch (1200F, 1200B) to the outside of the planting tool (11) and the implant (22) is not caught in the notch (1200F, 1200B). it can.

  In addition to the effect of the invention described in claim 1, the invention of claim 2 is provided with notches (1200F, 1200B) as front and rear end surfaces of the left hopper (1011L) and right hopper (1011R). Since the contact range of the mating surfaces is reduced when the planting tools (11, 1011) are closed, the contact sound can be suppressed.

  In addition, since the plate-like elastic members are provided on the front side and the rear side of the planting tool (11, 1011), it is possible to more reliably prevent the implant (22) from being caught in the notch (1200F, 1200B). , Transplantation accuracy is improved.

  According to the invention of claim 3, in addition to the effect of the invention of claim 2, the bolt (1240L, 1240R) is inserted into the planting tool (11, 1011) in accordance with the size of the implant (22). By adjusting the protrusion amount, the interval between the plate-like elastic members can be adjusted, so that the holding of the implant (22) is stabilized.

  According to the invention of claim 4, in addition to the effect of the invention of any one of claims 1 to 3, the scraper portion (1510) pushes the plate-like elastic member and enters the planting tool (11, 1011). By this, the soil etc. which adhered to the inside of a planting tool (11,1011) can be removed reliably.

  Moreover, in addition to the effect of the invention of any one of claims 1 to 4, the first related invention is that the planting tool (1011) is formed by forming the notch (1200F, 1200B). When closed, the contact range of the end face is reduced, so that the contact sound is suppressed.

  In addition, by providing the plate-like elastic member, the transplant (22) can be prevented from being caught in the notch (1200F, 1200B), so that the seedling planting accuracy is improved.

  Moreover, in addition to the effect of the invention of any one of claims 1 to 4 and the effect of the first related invention, the second related invention provides a recess (1210BU) at the upper edge of the plate-like elastic member. ) Is formed, the implant (22) can be prevented from coming into contact with the upper end of the plate-like elastic member when the implant (22) is supplied to the planting tool (11, 1011).

  Moreover, in addition to the effect of the invention of any one of claims 1 to 4 and the effect of the first or second related invention, the third related invention is based on the notch (1200F, 1200B). It can prevent that a transplant (22) falls outside the planting tool (11), and a transplant (22) is caught in a notch part (1200F, 1200B).

Left side view of seedling transplanter of Embodiment 1 of the present invention Plan view of the seedling transplanter of Embodiment 1 of the present invention (A): A schematic cross-sectional view of the center of the planting tool according to the first embodiment cut along a plane parallel to the longitudinal direction of the aircraft and perpendicular to the ground, and viewed from the left side, (b): Planting Schematic sectional view of the center part of the tool cut from a plane parallel to the left-right direction of the machine body and perpendicular to the ground and viewed from the back side, (c): Arranged along the rear surface inside the planting tool Perspective view of rear guard viewed from left rear In the first embodiment, the operation of the extraction member, the operation of the planting tool, and the operation timing of the lateral feed operation of the seedling table of the tray supply device are shown, and the operation of the extraction member, the operation of the planting tool, and the tray supply The figure which shows the operation timing of the vertical feed operation | movement of the tray feed rod of an apparatus (A)-(b): The perspective view of the tray supply apparatus of this Embodiment 1. FIG. Schematic side view showing the configuration of the tray vertical feeding device of the first embodiment Schematic perspective view of the take-out device of the first embodiment FIG. 7 is a schematic side view of the take-out device when the lower right front side is viewed from the upper left back side of the sheet of FIG. The schematic diagram which shows the rough correspondence of the position of rotation of the seedling drive arm and the position on the locus | trajectory of the front-end | tip part of a pair of extraction claw in the extraction apparatus of this Embodiment 1. FIG. Left side view of seedling planting device and seedling planting device drive mechanism of Embodiment 1 Schematic left side view of the seedling planting device drive mechanism of the first embodiment The top view explaining the various operation levers arrange | positioned in the vicinity of a pair of left and right handle grips of the steering handle of the first embodiment, and the operation unit The left view which shows schematic structure of the planting depth adjustment mechanism of this Embodiment 1. Schematic configuration diagram explaining input and output to the control unit of the first embodiment The perspective view which looked at the 2nd seedling planting device and the 2nd seedling planting device drive mechanism in this Embodiment 2 from the left back of the body. The perspective view which looked at the 2nd seedling planting device and the 2nd seedling planting device drive mechanism which were shown in Drawing 15 from the right side of the body The perspective view which looked at the 2nd seedling planting device shown in Drawing 15, and the 2nd seedling planting device drive mechanism from the left front of the body (A): It is a figure for showing the 2nd front guard and the 2nd back guard in this Embodiment 2, and the central part of the 2nd planting tool is parallel to the direction of the body and perpendicular to the ground. A schematic cross-sectional view cut from a plane and viewed from the left side, (b): a view for showing a second front guard, in which the central part of the second planting tool is parallel to the left-right direction of the body and perpendicular to the ground Schematic cross-sectional view of cut from a plane and viewed from the back side (A): Schematic cross-sectional view of the center of the second planting tool cut from a plane parallel to the longitudinal direction of the aircraft and perpendicular to the ground and viewed from the left side, (b): Second planting tool The cross section which cut | disconnected the center part of the plane in the plane parallel to the left-right direction of an airframe, and perpendicular | vertical to the ground, and was seen from the back side, (c): The perspective view which looked at the 3rd front guard from the right rear Schematic plan view to explain the load adjustment lever Schematic side view for explaining a configuration for raising the pressure-reducing wheel to a non-working position It is a figure which shows a left seedling holding board and a right seedling holding board about the 3rd planting tool in one Example related to this invention, The center part of the 3rd planting tool is parallel to a body left-right direction, and is on the ground. Schematic cross-sectional view of cut from a vertical plane and viewed from the back side

  Hereinafter, a seedling transplanter according to an embodiment of the transplanter of the present invention will be described.

(Embodiment 1)
In Embodiment 1, a seedling transplanter according to an embodiment of the transplanter of the present invention will be described with reference to the drawings.

  FIG. 1 shows a schematic left side view of the seedling transplanter 1 of the present embodiment, and FIG. 2 shows a schematic plan view.

  As shown in FIGS. 1 and 2, a seedling transplanter 1 for transplanting seedlings such as vegetables includes a traveling vehicle body 15 including a pair of left and right front wheels 2 and rear wheels 3 as traveling wheels, and a front portion of the traveling vehicle body 15. The planting tool 11 is swung up and down to plant the seedlings 22 (see FIG. 5) arranged at the rear of the traveling vehicle body 15 and the engine 12 and the transmission case (also referred to as main transmission case) 4 arranged in the field. Take out the seedling planting device 300, the tray supply device 100 for supplying the tray 20 (see FIG. 5) containing the seedlings 22 and the breeding pot 21 (see FIG. 5) of the tray 20 of the tray supply device 100. A planting depth adjusting mechanism 700 including a take-out device 200 for entering the member 260 to take out the seedling 22 and supplying it to the planting tool 11 and a sensor plate 710 for keeping the planting depth of the seedling 22 constant (FIG. 13) Wheel 13 is configured to include a steering wheel 8, and arranged in the center of the steering wheel 8 operating section 600 or the like.

  In addition, as shown in FIG. 2, the tray supply device 100 is provided with a tray detection device 1100 for detecting that the tray 20 is not placed on the tray conveyance path 111.

  In the feeding operation of the tray supply device 100 of the seedling transplanter 1 according to the present embodiment, (1) the seedling stand 110 is arranged so that the seedlings in the seedling pot 21 for one row in the horizontal direction of the tray 20 are sequentially taken out by the takeout member 260. However, after the horizontal feeding operation intermittently sent in the horizontal direction and (2) the removal of the seedlings from all the seedling pots 21 for one row in the horizontal direction is completed, the tray 20 on the seedling table 110 is moved to the tray feeding rod. There is a vertical feed operation in which the row of the seedling pots 21 is fed downward by 121 in a downward direction.

  The vertical feed by the tray feed rod 121 is in a state where the tip of the tray feed rod 121 is engaged with the groove between the adjacent seedling pots 21 on the back side of the tray 20, and in this state, the tray feed rod 121 is substantially in a side view. The tray 20 is rotated by drawing a square locus A (see FIG. 6), and the tray 20 is intermittently vertically fed along the tray conveyance path 111.

  The detailed configuration of the tray supply device 100, the tray detection device 1100, and the take-out device 200 will be described later with reference to FIGS.

  As shown in FIGS. 1 and 2, the rotational power output from the engine 12 is branched by the mission case 4 and transmitted to the pair of left and right rear wheels 3 via the pair of left and right traveling transmission cases 9. It is the structure transmitted also to the planting transmission 18 provided in the rear side of the mission case 4.

  That is, in the seedling transplanter 1 of the present embodiment, the power from the mission case 4 is transmitted to the planting transmission device 18 to take out the seedling 22 from the seedling pot 21 and plant it in the groin of the field, and the chain belt. While being transmitted to the take-out device 200 through 202, it is transmitted to the planting tool 11 through the seedling planting device drive mechanism 400 attached to the planting transmission device 18 and the seedling planting device 300.

  In addition, the planting operation of the seedling transplanter 1 of the present embodiment is configured to be intermittently performed by the seedling planting device drive mechanism 400.

  The detailed configurations of the seedling planting device 300 and the seedling planting device driving mechanism 400 will be described later with reference to FIGS.

  Here, the planting tool 11 is demonstrated using Fig.3 (a)-FIG.3 (c).

  3A is a schematic cross-sectional view of the center portion of the planting tool 11 cut from a plane parallel to the longitudinal direction of the machine body and perpendicular to the ground, and viewed from the left side, FIG. FIG. 3 is a schematic cross-sectional view of the center of the planting tool 11 cut from a plane parallel to the left-right direction of the body and perpendicular to the ground, and viewed from the back side. FIG. It is the perspective view which looked at the rear guard 1210B arrange | positioned along the inner rear surface from the left rear.

  As shown in FIGS. 3 (a) and 3 (b), the planting tool 11 includes a pair of left and right left hopper portions 1011L and 1011R, and a left hopper portion 1011L, which temporarily hold seedlings and plant them in a field. The left hopper holder 1012L and the right hopper holder 1012R, which hold the upper end portion of the right hopper portion 1011R and can be separated from each other so as to open and close the front end sides of the left hopper portion 1011L and the right hopper portion 1011R; 1012L and the right hopper holder 1012R are fixed to the holder holding frame 1013 that can pivot about the fulcrum shaft 1013a, and the lower left side of the left hopper holder 1012L and the right hopper holder 1012R. Part 1011L and right hopper part 10 The left and right sides of the hopper tension spring 1014 that constantly urges the compression force in the closing direction of the 1R, and the left and right hopper holders 1012L and 1012R are fixed to the front upper ends of the left and right hopper holders 1012R. A pair of opening / closing arms 1015L and 1015R is provided.

  Here, the connecting portion 1012La of the left hopper holder 1012L and the connecting portion 1012Ra of the right hopper holder 1012R have a gear shape, and the gear shape is shifted by half a tooth at the front and rear, and the gears are assembled by facing the left and right sides. Is configured to mesh. Specifically, when the right opening / closing arm 1015R fixed to the right hopper holder 1012R and connected to the other end 352 of the opening / closing connection cable 350 is pulled by the opening / closing connection cable 350, the right hopper holder 1012R. The connecting portion 1012Ra rotates about the fulcrum shaft 1013a in the direction in which the right hopper portion 1011R opens. At the same time, when the gear meshes with the connecting portion 1012Ra of the right hopper holder 1012R, the connecting portion 1012La of the left hopper holder 1012L rotates in conjunction with each other, so that the left hopper portion 1011L rotates simultaneously.

  The open / close cam 322 (see FIG. 10), the hopper tension spring 1014, the pair of left and right open / close arms 1015L and 1015R, the open / close arm 340 (see FIG. 10), the open / close connection cable 350 (see FIG. 10), etc. The component which includes is an example of the planting tool opening and closing mechanism of the present invention.

  Further, the pair of left and right hopper portions 1011L and 1011R have a substantially cylindrical shape in which the lower end portion is pointed like a bowl in the closed state and the upper end portion is opened.

  The front and rear end surfaces where the left hopper portion 1011L and the right hopper portion 1011R face each other have a substantially V-shaped front V-shaped notch portion 1200F in front view and a substantially V-shape in rear view. A rear V-shaped notch 1200B is provided.

  By providing the front V-shaped notch portion 1200F and the rear V-shaped notch portion 1200B, when the planting tool 11 is closed, the contact portion between the mating surfaces of the left hopper portion 1011L and the right hopper portion 1011R becomes small. Noise generated by hitting the mating surfaces can be reduced.

  In addition, the planting tool 11 of the present embodiment includes a front guard 1210F that covers the front V-shaped notch 1200F from the inside and a rear guard 1210B that covers the rear V-shaped notch 1200B from the inside.

  The front guard 1210F has an upper end portion 1210Fa fixed to the front rising portion 1013F of the holder holding frame 1013, and extends obliquely downward toward the inner center of the planting tool 11 from a side view thereof (see FIG. 3A). The flat plate portion is configured to substantially cover the front V-shaped notch portion 1200F in rear view (see FIG. 3B).

  The rear guard 1210B has a left upper end 1210BL and a right upper end 1210BR fixed to the rear end side of the left frame portion 1013L and the rear end side of the right frame portion 1013R of the holder holding frame 1013. 3 (a)), a flat plate portion extending obliquely downward toward the inner center of the planting tool 11 is configured to substantially cover the rear V-shaped notch portion 1200B in the same manner as the front guard 1210F.

  Further, the upper edge 1210BU of the flat plate portion of the rear guard 1210B (see FIG. 3C) is fixed to the holder holding frame 1013, and the rear upper edge 1011BU of the pair of left and right hoppers (FIG. 3 ( It is configured so as to be the same height as the reference a). That is, the upper end edge portion 1210BU of the rear guard 1210B is configured to be lower than the heights of the left and right upper end portions 1210BL and 1210BR of the rear guard 1210B in the rear view. The upper end edge portion 1210BU configured to be low corresponds to an example of the concave portion of the present invention.

  The front guard 1210F and the rear guard 1210B are elastic or resin plate members. The front guard 1210F and the rear guard 1210B of the present embodiment are an example of the plate-like elastic member of the present invention.

  By providing the front guard 1210F and the rear guard 1210B, when the take-out device 200 supplies the seedling 22 to the planting tool 11, the seedling 22 is planted from the front V-shaped notch 1200F or the rear V-shaped notch 1200B. It is possible to prevent the seedling 22 from being dropped out of the attachment 11 or caught in the front V-shaped notch 1200F or the rear V-shaped notch 1200B, and the transplanting accuracy of the seedling is improved.

  In addition, the upper edge portion 1210BU of the rear guard 1210B has the same height as the rear upper edge portion 1011BU (see FIG. 3A) of the pair of left and right hopper portions or lower than the upper edge portion. Since the height of 1210BU is configured to be lower than the heights of the left and right upper end portions 1210BL and 1210BR of the rear guard 1210B in the rear view, when the take-out device 200 supplies the seedling 22 to the planting tool 11, the seedling A part of 22 can be prevented from coming into contact with the upper edge 1210BU of the rear guard 1210B, and the seedling 22 can be accurately fed into the hopper without being damaged.

  Next, returning to FIG. 1 and FIG. 2, the configuration of the seedling transplanter 1 will be described.

  That is, the main frame 17 extending to the right side is provided at the rear of the left and right frames 16 arranged in the left and right direction at the rear end of the mission case 4. A steering handle 8 extending rearward from the left and right ends is provided at the rear end of the main frame 17, and the steering handle 8 is supported by the transmission case 4 via the main frame 17 and the left and right frames 16. Yes.

As a result, the worker walks behind the traveling vehicle body 15 with the steering handle 8 while walking.
5 steering operations can be performed.

  That is, the seedling transplanter 1 according to the present embodiment is accommodated in the tray 20 while the traveling vehicle body 15 is advanced with the pair of left and right front wheels 2 and 2 and the pair of left and right rear wheels 3 and 3 straddling the heel U. It is the structure which can be planted automatically on the upper surface of the ridge U.

  The traveling unit is provided with an airframe control mechanism 500 that moves the pair of left and right rear wheels 3 and 3 up and down relative to the traveling vehicle body 15 to control the posture and the vehicle height of the traveling vehicle body 15.

The airframe control mechanism 500 includes a hydraulic lift cylinder 10 that lifts and lowers the traveling vehicle body 15 by raising and lowering the rear wheel 3 between the traveling transmission case 9 and the traveling vehicle body 15 of the pair of left and right rear wheels 3, and the traveling vehicle body 15. A horizontal hydraulic cylinder 14 for tilting is provided, and when the hydraulic lifting cylinder 10 is extended and contracted, the pair of left and right rear wheels 3 travels in the same direction by the same amount.
The traveling vehicle body 15 moves up and down.

  The hydraulic lift cylinder 10 is fixedly provided to a hydraulic pressure switching valve portion 40 (see FIG. 1) attached to the upper part of the mission case 4 and switches hydraulic pressure to switch the hydraulic pressure from the hydraulic pump attached to the mission case 4. This is a configuration that operates by operating a lifting operation valve (not shown) provided in the valve unit 40.

  Note that a lift operation lever 81 (see FIG. 12), which will be described later, is connected to the lift operation valve via a cable 82, and a counter arm 760 (see FIG. 13), which will be described later, is connected via a rod 765. .

  Further, a pendulum-type left / right tilt sensor 41 is provided on the right side of the mission case 4, and is detected by the left / right tilt sensor 41 through a horizontal operation valve (not shown) provided in the hydraulic pressure switching valve unit 40. The hydraulic cylinder 14 is actuated, and only the left rear wheel 3 is moved up and down to keep the traveling vehicle body 15 horizontal regardless of the unevenness of the troughs of the eaves U.

  Next, the operation timing of the extraction member 260, the planting tool 11, the tray supply device 100, and the tray feed rod 121 described above will be described mainly with reference to FIG.

  FIG. 4 shows the operation timing of the extraction member 260, the operation of the planting tool 11, and the operation timing of the transverse feed operation of the seedling table 110 of the tray supply device 100, and the operation of the extraction member 260, the operation of the planting tool 11, FIG. 5 is a diagram illustrating the operation timing of the vertical feed operation of the tray feed rod 121 of the tray supply device 100.

  The vertical feed operation is an operation that is executed when the seedling placing stand 110 moves to the extreme left and right end and the seedling 22 of the last seedling pot 21 is extracted.

  The horizontal axis in FIG. 4 is based on the rotation angle of various drive arms from the horizontal direction. For example, in the case of the take-out member 260, the rotation angle of the drive arm 220 (see FIG. 7), the rotation angle of the vertical movement arm 320 (see FIG. 10) in the case of the planting tool 11, the vertical angle by the tray supply device 100. In the case of feeding, the rotation angle of the longitudinal feed drive arm 150 (see FIG. 6) is used as a reference.

  As shown in FIG. 4, according to the operation timing 2210 of the extraction claw, the seedling transplanter 1 of the present embodiment is pulled out while the extraction member 260 holds the seedling 22 from the inside of the breeding pot 21 at the timing P2. Release of the seedling 22 to the planting tool 11 is started before the timing P3, the release of the seedling 22 is terminated at the timing P3, and then the inside of the adjacent seedling pot 21 is entered at the timing P4. After grasping the seedling 22, it is configured to come out of the inside of the seedling pot 21 (see timing P2 in FIG. 4).

  Moreover, as shown in FIG. 4, according to the operation timing 2220 of the planting tool, the seedling transplanter 1 of the present embodiment stops the descending operation of the planting tool 11 at the timing P3 slightly lowered from the top dead center. After that, it is configured to reach the bottom dead center at timing P4.

  Here, at the timing P3 when the planting tool 11 stops the descending operation, the operation of the take-out member 260, the lateral feed operation of the tray supply device 100 (ie, the operation of the seedling table 110) and the vertical feed operation (ie, the tray feed rod). The operation related to the planting operation including the operation 121) is stopped at the same time, so that the planting operation can be performed intermittently and adjustment between the planting stocks is possible. In addition, the stop period of these operation | movements is comprised by the operation part 600 (refer FIG. 12) from 0 second to a predetermined period according to the desired planting stock.

  The structure for intermittently realizing the planting operation is realized by the planting clutch 420, the intermittent cam 441, the solenoid 470, and the like in the seedling planting device drive mechanism 400, which will be described later with reference to FIG. To do.

  In addition, as shown in FIG. 4, according to the operation timing 2230 of the lateral feed operation in the seedling table 110 of the tray supply device 100, the seedling transplanter 1 of this embodiment has the takeout member 260 rushing into the seedling pot 21. During the operation, that is, from timing P4 to P2, the horizontal feeding operation for one seedling pot 21 is stopped, and at the timing P3 when the planting operation of the planting tool 11 is stopped, the seedling is raised. In the middle of the horizontal feeding operation for one pot 21, the horizontal feeding operation is also stopped at the same time.

  Further, as shown in FIG. 4, according to the operation timing 2240 of the vertical feed operation in the tray feed rod 121 of the tray supply device 100, the seedling transplanter 1 of the present embodiment is configured so that the tray feed rod 121 is seen from the side. The tip of the tray feed rod 121 is pulled out from the gap 21a (see FIG. 6) between the adjacent seedling pots 21 on the back side of the tray 20 in the rotation operation while drawing a substantially rectangular locus A (see FIG. 6). (See arrow 121a1 in FIG. 6), move upward (see arrow 121a2 in FIG. 6), and again enter the gap 21b (see FIG. 6) between the next seedling pots 21 (see arrow 121a3 in FIG. 6). The return operation up to is started after the takeout member 260 enters the inside of the seedling pot 21 and the takeout member 260 comes out of the inside of the seedling pot 21 (timing in FIG. 4). 2 reference) was just completed, starts the longitudinal feed operation at timing P2, is completed constitutes the longitudinal feed operation at timing P3.

  In FIG. 4, for the purpose of facilitating understanding, the tray feed rod 121 is moved into the seedling pot by the operation timing 2250 with the same content as the operation timing 2240 of the vertical feed operation in the tray feed rod 121 of the tray supply device 100 described above. It is shown from the viewpoint of whether it is in the groove part between 21 or has come out.

  With the above configuration, during the return operation of the tray feed rod 121 (see timings P1 to P2 in FIG. 4), since the takeout member 260 has rushed into the seedling pot 21, the tray 20 is pressed by the takeout member 260. Therefore, the tray 20 can be prevented from shifting downward on the tray conveyance path 111.

  In addition, with the above configuration, when the planting operation of the planting tool 11 is stopped by intermittent planting, the vertical feed operation of the tray 20 by the tray feed rod 121 is completed (see timing P3 in FIG. 4). The tray feed rod 121 can reliably hold the tray 20 in a stopped state in intermittent planting, and the tray 20 can be prevented from shifting downward on the tray conveyance path 111.

  That is, in the intermittent planting stop state, as described above, the members related to the planting operation stop simultaneously, so that the tray 20 is likely to be displaced due to vibration or the like due to traveling of the airframe, but in this embodiment, the tray 20 The vertical feed operation of the tray 20 by the feed rod 121 has been completed, and the tray feed rod 121 is stopped while remaining in the gap 21a (see FIG. 6) between the adjacent seedling pots 21, The tray feed rod 121 can reliably hold the tray 20.

  In addition, with the above configuration, while the take-out member 260 enters the inside of the seedling pot 21, the tray transport path moving device 170 does not perform the lateral feeding operation of the seedling table 110 of the tray supply device 100, and is intermittent. When the planting operation of the planting tool 11 is stopped by the planting operation (see timing P3 in FIG. 4), one seedling pot 21 of the seedling table 110 of the tray supply device 100 by the tray transport path moving device 170 is used. Since it is in the middle of the horizontal feed operation, the horizontal feed for one seedling pot 21 of the tray 20 can be operated slowly and with sufficient margin at a timing that does not hinder the seedling extraction operation, and the accuracy of the horizontal feed can be improved. improves.

  Further, in the present embodiment, while the tray feed rod 121 is performing the return operation, the tray transport path moving device 170 does not perform the lateral feed operation of the seedling table 110 of the tray supply device 100. This is because, while the tray feed rod 121 is returning to move the next horizontal row of seedling pots 21 downward, the horizontal feed operation (in this case, the seedling table 110 moves to the extreme end). Therefore, if the holding of the tray 20 is not stable while the tray feeding rod 121 is returning, the lateral feeding operation will be performed. This is because the tray 20 may be displaced by the lateral feed operation of the tray supply device 100 by the tray transport path moving device 170. Thereby, in this Embodiment, it can prevent that the tray 20 slip | deviates by the horizontal feed operation | movement of the tray supply apparatus 100 by the tray conveyance path moving apparatus 170. FIG.

  Moreover, according to the seedling transplanting machine 1 of the present embodiment, the tray 20 can be realized with a stable vertical feed that is not easily displaced, and a tray supply device 100 including a vertical feed mechanism different from the conventional one can be provided. The degree of freedom of design increases.

  Next, the tray supply apparatus 100 described above will be further described mainly with reference to FIGS. 5 (a), 5 (b), and 6. FIG.

  FIG. 5A is a perspective view of the tray supply apparatus 100, and FIG. 5B is an enlarged perspective view of a portion X in FIG. 5A. FIG. 6 is a schematic side view illustrating the configuration of the tray vertical feeding device 120 of the tray supply device 100.

  The tray 20 is formed by connecting a plurality of seedling pots 21 vertically and horizontally, is formed of plastic, and is configured to retain flexibility. Each seedling pot 21 is connected on the front surface side, and the back surface is in an independent form.

  The tray supply device 100 includes a seedling table 110 having a tray conveyance path 111 inclined downward to support the bottom of the tray 20, and a tray vertical feeding device that intermittently feeds the tray 20 in the vertical direction along the tray conveyance path 111. 120 and a tray transport path moving device 170 (see FIG. 2) for moving the seedling table 110 having the tray transport path 111 in the left-right direction.

  In addition, as described above, the tray supply device 100 is provided with the tray detection device 1100 for detecting that the tray 20 is not placed on the tray conveyance path 111.

  Here, the configuration and operation of the tray detection apparatus 1100, which is one of the characteristics of the seedling transplanter 1 of the present embodiment, will be described with reference to FIGS.

  That is, as shown in FIGS. 2 and 5, the tray detection device 1100 is provided on a tray detection member 1110 that is pivotally disposed in a substantially central portion of the tray conveyance path 111 and on the left and right outer surfaces of the seedling table 110, respectively. A pair of left and right interlocking arms 1120L and 1120R that are arranged and rotate in conjunction with the rotation of the tray detection member 1110, a connecting shaft 1130 that connects the tray detection member 1110 and the pair of left and right interlocking arms 1120L and 1120R, and a tray A pair of left and right limiter switches 1140L and 1140R are provided on the inner surfaces of the left and right side portions 172L and 172R of the transport path moving device 170, respectively, at positions corresponding to the pair of left and right interlocking arms 1120L and 1120R. Signal lines (not shown) of the pair of left and right limiter switches 1140L and 114R are connected to the control unit 800 (see FIG. 14).

  When the tray 20 is not supplied on the tray conveyance path 111 or when the rear end portion of the tray 20 passes the position of the tray detection member 1110, the tray detection member 1110 is a spring member (not shown). Is omitted toward the front side from the substantially central portion of the tray conveyance path 111, but when the tray 20 is supplied onto the tray conveyance path 111, the back surface of the tray 20 is attached to the spring member. Since the tray detection member 1110 is pressed by a force that opposes the restoring force, the tray detection member 1110 rotates counterclockwise when viewed from the left side.

  As a result, the tray detection member 1110 rotates clockwise or counterclockwise in accordance with the presence or absence of the tray 20, and the pair of left and right interlocking arms 1120L and 1120R rotate in conjunction therewith.

  In a state where the tray 20 does not exist in the central portion on the tray conveyance path 111, the tray detection member 1110 rotates clockwise as viewed from the left side and faces from the opening at the substantially central portion of the tray conveyance path 111 to the front side. At the same time, the pair of left and right interlocking arms 1120L and 1120R rotate clockwise in conjunction with this and stop at a predetermined position. When the seedling table 110 is laterally fed and reaches the inner surface of either of the left and right side portions 172L and 172R of the tray transport path moving device 170, the pair of left and right interlocking arms 1120L or 1120R is moved to the pair of left and right limiter switches 1140L. Alternatively, a signal indicating that the tray 20 does not exist at a substantially central portion on the tray conveyance path 111 is sent to the control unit 800 when it hits the movable portion 1141L or 1141R of 1140R. Receiving the signal, the control unit 800 sounds an alarm buzzer (not shown) arranged in the operation unit 600 (see FIG. 12).

  The alarm buzzer is configured to sound for a certain time (several seconds) after the movable part 1141L or 1141R of the pair of left and right limiter switches 1140L or 1140R is pressed, and then the alarm sound of the alarm buzzer automatically stops.

  In addition, the certain time is set to be equal to or longer than the time when the seedling table 110 moves from end to end, and each time the movable unit 1141L or 1141R of the pair of left and right limiter switches 1140L or 1140R is pressed, the certain time is counted. Is reset, a signal from the newly pressed limiter switch 1140L or 1140R is received, and the count for a predetermined time is newly started, so that the alarm sound is stopped until the tray 20 is supplied. It can be set as the structure which rings continuously without.

  As described above, the pair of left and right limiter switches 1140L and 1140R are attached to the left and right side portions 172L and 172R of the tray transport path moving device 170, which is a fixed portion that does not move to the left and right. The signal wiring (not shown) extending from can be securely fixed, and disconnection can be prevented.

  Further, since the alarm buzzer automatically stops when a warning sound is generated for a certain time, it is not necessary to provide a stop switch.

  In the above embodiment, the configuration in which the alarm buzzer sounds for a certain period of time has been described. However, the configuration is not limited thereto. For example, when the tray detection device 1100 detects the absence of the tray 20, the horizontal row of the tray 20 is linked with the solenoid 470. For example, the alarm buzzer may sound 10 times according to the number of the seedling pots 21 arranged in the above.

  In the above embodiment, the configuration in which the alarm buzzer sounds for a certain period of time has been described. However, the present invention is not limited to this. For example, when the tray detection device 1100 detects the absence of the tray 20 twice in succession, it continues for several seconds. The alarm buzzer may sound or the alarm buzzer may sound longer in conjunction with the solenoid 470 each time the absence of the tray 20 is detected.

  According to the said structure, since the residual amount of a seedling is known by the sound of an alarm buzzer, the tray 20 can be replaced with a margin.

  Moreover, according to the said structure, there exists an effect that it can judge the seedling reduction degree and the seedling residual quantity degree by operating an alarm for every intermittent planting operation interlocked with the operation of the solenoid 470.

  Here, the description returns to the tray vertical feeding device 120 of the tray supply device 100 again.

  The tray vertical feeding device 120 enters between the seedling pots 21 protruding from the back side of the tray 20 to the back side, and moves downward to feed the tray 20 by one horizontal row of the seedling pot 21, The tray feed rod 121 is configured to move out from between the seedling pots 21 and move upward by the horizontal row of the seedling pots 21. The tray feed rod 121 is configured such that a central portion 121a can enter and exit from a retreat groove 111a provided at a lower portion of the tray conveyance path 111, and both end portions 121b are bent at a right angle so as to be outside of both sides of the tray conveyance path 111. The configuration is such that the tray 20 does not get in the way when the tray 20 moves on the tray conveyance path 111.

  Further, the tray supply device 100 includes a pair of left and right rod guide plates 112 for restricting the movement of the tray feed rod 121 on the end surface portions on both sides of the tray conveyance path 111 on the downstream side of the retreat groove 111a. Yes. At the upper end edge of the rod guide plate 112, a notch 112a is formed into which a protrusion 121ab protruding downstream at both ends of the central portion 121a of the tray feed rod 121 can enter (FIG. 5B). reference).

  That is, the notch portion 112a is temporarily formed between the center portion 121a of the tray feed rod 121 until the center portion 121a of the tray feed rod 121 moves downward and then comes out from between the seedling pots 21. The protrusions 121ab at both ends are held and the tray 20 is prevented from moving downward due to the weight of the seedlings 22 placed in the seedling pot 21. The trajectory of the central portion 121a of the tray feed rod 121 will be described later with reference to FIG.

  Further, the tray transport path moving device 170 is provided on the back side of the tray transport path 111 and obtains a driving force from the main body side of the seedling transplanter 1 to move the seedling table 110 having the tray transport path 111 in the left-right direction. A lead cam shaft 171, a guide rail 155 that is provided above the lead cam shaft 171 and guides the movement of the seedling table 110 having the tray conveyance path 111 in the left-right direction, and both left and right side portions 172 </ b> L that hold the guide rail 155 on both the left and right sides , 172R.

  Further, the tray transport path 111 is supported by a lead cam shaft 171 and a guide rail 155 that guides left and right movement provided on the inner upper side of the tray transport path 111. As a result, the guide rail 155 supports the tray conveyance path 111 at a position away from the lead cam shaft 171, so that there is little backlash when moving in the left-right direction.

  When the tray 20 is inserted from above the seedling mount 110 so as to be sandwiched between the tray conveyance path 111 and the presser frame 25, the tip of the tray feed rod 121 is engaged with the groove on the back side of the tray 20. In this state, the tray feed rod 121 rotates while drawing a substantially square locus A in a side view, whereby the tray 20 is intermittently fed vertically downward along the tray conveyance path 111.

  A mechanism for intermittently feeding the tray 20 intermittently using the tray feed rod 121 will be described later.

  Further, in the present embodiment, the tray 20 is sequentially vertically fed along the tray conveyance path 111 and the seedlings 22 are all taken out by the take-out member 260, and then pass below the tray vertical feed device 120 and finally. In particular, it is configured to pass above the operation unit 600 and be discharged in the direction of the operation handle 8 (see the discharge path 20t in FIG. 1), and this point will be described.

  That is, as shown in FIGS. 1 and 2, the main clutch lever 900 is disposed at the tip of the discharge path 20t through which the tray 20 is discharged. When the main clutch lever 900 is operated forward, the main clutch is “on”. When the operation is performed rearward (see the arrow 900B in FIG. 1), the main clutch enters the “disengaged” state.

  The tray 20 discharged in the direction of the operation handle 8 is normally removed by an operator. However, even if the operator neglects the removal operation of the tray 20 that has been discharged, in this embodiment, the tray 20 is discharged. When the main clutch lever 900 is pushed backward by the leading end of the tray 20 (see arrow 900B in FIG. 1), the planting operation is automatically stopped for safety. is there.

  By the way, the take-out device 200 is arranged at a position facing the lower end of the seedling table 110, and the tip of the take-out member 260 operates so as to draw a trajectory K, and sequentially from the seedling pot 21 that moves in the lateral direction. The seedling 22 is taken out and supplied to the planting device 7.

  Next, the configuration of the extraction device 200 provided in the seedling transplanter 1 according to the present embodiment will be mainly described with reference to FIGS.

  FIG. 7 is a schematic perspective view of the take-out device 200, and FIG. 8 is a schematic side view of the take-out device 200 as seen from the upper left back side of the paper surface of FIG.

  As shown in FIGS. 7 and 8, the take-out device 200 is rotatably held by an take-out device fixing member 201 fixed to the main body of the seedling transplanter 1, and is connected to the main body side drive source via the chain belt 202. A drive arm 220 that is rotated in the same direction by a drive shaft 203 that is rotated in the direction of arrow B by power, a connecting arm 230 in which one end portion 230a is rotatably connected to a distal end side portion 220a of the drive arm 220; A plate-like member that is held on the take-out device fixing member 201 by fixing pins 201a and 201b and has an outer shape of an approximately J letter, and the side closer to the tray supply device 100 is straight and the far side is substantially R-shaped. And a guide portion 240 having a guide groove 241 that has a shape rising up.

  Further, the take-out device 200 includes a first guided member 245 that is integrated with a cam shaft 271 to be described later and inserted into the guide groove 241 so as to be smoothly slidable without shaking. The substrate 250 is connected to the member 247, protrudes from one end of the side surface to which the guided members are connected, and is bent at a substantially right angle, and the substrate 250 protrudes perpendicularly from the bent portion 251 of the substrate 250. A pair of left and right extraction claw holding pins 252L and 252R, which are movably held, and a root portion are attached to a pair of left and right extraction claw holding pins 252L and 252R, respectively, and the width of the tip portion is narrowed into a tweezers. 21 and a pair of extraction claws 261L, 261R for taking out the seedling 22 in the 21 and a base portion side of the inner surface portion of the pair of extraction claws 261L, 261R facing each other. A take-out member 260 and a spring 263 pulling the opposite ends is mounted, and a.

  Further, the take-out device 200 is a cam 270 having a cam shaft 271 integrated with the first guided member 254, which is pivotably penetrated through the substrate 250, and is related to the thickness of the outer peripheral portion of the cam 270. The outer peripheral portion 272 whose thickness varies depending on the location of the outer peripheral portion when contacting the front end surfaces of the pair of left and right claw tip width regulating projections 262L, 262R provided on the inner surface portions of the pair of extraction claws 261L, 261R. And an outermost edge portion 273 whose outer diameter changes depending on the position of the outermost edge portion with respect to a distance (also referred to as an outer diameter) of the outermost edge portion of the cam 270 from the axis center of the cam shaft 271. The cam 270 is pivotally connected to the substrate 250, and is removed from the seedling pot 21 along the pair of take-out claws 261L and 261R by a change in the outer diameter of the outermost edge 273 of the cam 270. Take-out pawl 261L, and a, a pushing mechanism 280 for pushing the seedlings 22 held by 261R.

  Further, the edge portion 245 a near the tip of the first guided member 245 that is integral with the cam shaft 271 is rotatably connected to the other end 230 b of the connecting arm 230. The first guided member 245 that is integral with the camshaft 271 passes through a transmission mechanism 290 including a first gear 291, a second gear 292, and a third gear 293 by the rotational force of the drive arm 220. The driving force is transmitted to the cam shaft 271 in accordance with the driving cycle of the driving arm 220 by being rotated.

  Further, when the outer peripheral portion 272 of the cam 270 comes into contact with the front end surfaces of the pair of left and right claw tip width regulating protrusions 262L and 262R provided on the inner surface side of the pair of extraction claws 261L and 261R, the outer peripheral portion 272 of the cam 270 The pair of extraction claws 261L and 261R is opened and closed by the interaction between the change in thickness and the restoring force of the tension spring 263.

  Next, the transmission mechanism 290 will be further described.

  That is, the first gear 291 is fixed to the distal end side portion 220a of the drive arm 220, and is rotatably attached to the connection arm 230 via the first rotation shaft 291a. Further, the third gear 293 is fixed to the tip end portion 245 b of the first guided member 245 that is integral with the cam shaft 271, and the edge portion 245 a near the tip end of the first guided member 245 is connected to the connecting arm 230. Therefore, the third gear 293 is rotatably held with respect to the connecting arm 230. Therefore, the third gear 293 rotates integrally with the first guided member 245. The second gear 292 is pivotally attached at the center position of the connecting arm 230, and is sandwiched between both the first gear 291 and the third gear 293, and is engaged with both gears.

  Next, the extrusion mechanism 280 will be further described mainly with reference to FIG.

  The extruding mechanism 280 pushes out the seedling 22 held by the pair of extraction claws 261L, 261R. The tip portion 281a is bent at a right angle to form a notch 281b that matches the width of the tip portion of the extraction claws 261L, 261R. An extrusion rod 281 and a connecting rod 282 bent at a substantially right angle, one end portion 282a of which is rotatably inserted into a rear end hole portion 281c provided at the rear end portion of the extrusion rod 281. The connecting rod 282 held by a pull-out preventing pin (not shown), the other tip 282b of the connecting rod 282 are fixed to the upper end 283a, and the lower end 283b is fixed to the substrate 250 by the push arm connecting shaft 283d. A push-out arm 283 that is pivotally attached and provided with a tension spring holding first projection 283c in the center, and one end of the tension spring holding first projection. Hooked to 83c, the other end is provided with a spring 284 pulling the push-out arm hooked to the second projection 250a for the tension spring held fixed to the substrate 250.

  Then, when the cam 270 rotates in the direction of arrow B, the protruding portion 273b having an outer diameter larger than that of the other portion 273a in the outermost edge portion 273 is the outer peripheral edge portion of the root portion of the first projection 283c for holding the tension spring. , The push-out arm tension spring 284 is extended, and the push-out arm 283 is rotated counterclockwise in FIG. 8 so that the push-out rod 281 connected by the connecting rod 282 moves backward. Yes (see arrow C). Further, when the cam 270 rotates in the direction of arrow B, the other portion 273a having an outer diameter smaller than the protruding portion 273b in the outermost edge portion 273 is the outer peripheral edge portion of the root portion of the first projection 283c for holding the tension spring. , The push-out arm tension spring 284 is contracted, and the push-out arm 283 is rotated clockwise in FIG. 8 so that the push-out rod 281 connected by the connecting rod 282 protrudes (arrow). D). Each time the push rod 281 protrudes, the tip of the pair of extraction claws 261L and 261R passes through the notch 281b provided in the tip 281a of the push rod 281. It is a configuration that removes the soil that had been removed.

  Here, although the extrusion rod 281 has a flat upper portion, it can prevent the leaves of the seedling 22 from being entangled with the pair of extraction claws 261L and 261R.

  Next, the operation of the take-out device 200 in the above configuration will be described with reference to FIGS.

  As described above, the guide portion 240 does not move because it is firmly fixed to the extraction device fixing member 201 fixed to the main body of the seedling transplanter 1.

  As the drive arm 220 rotates, the connecting arm 230 swings. The movement of the connecting arm 230 passes through the guide groove 241 formed in the guide portion 240 and is connected to the substrate 250. Regulated by H.245.

On the other hand, the substrate 250 also swings along with the movement of the connecting arm 230. In addition to the first guided member 245, the second guided member 247 penetrates the guide groove 241 in the substrate 250. Since the second guided member 247 is not connected to the connecting arm 230, the movement repeats reciprocating movement along the guide groove 241. Since the extraction member 260 is attached to the substrate 250, the extraction member 260 moves in the same manner as the substrate 250, and the pair of extraction claws 26.
The leading ends 261Lp and 261Rp of 1L and 261R draw a locus K shown in FIGS.

Here, FIG. 9 is a schematic diagram showing a general correspondence relationship between the rotation position of the drive arm 220 and the position on the locus K of the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R. The rotation positions P1 to P6 of the drive arm 220 shown in FIG. 9 correspond to the positions K1 to K6 on the locus K of the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R. still,
The arrow described on the broken line indicating the locus K indicates the direction of movement.

  As shown in FIG. 9, the operation of the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R from the position K1 to the position K2 corresponds to the operation of extracting the seedling 22 from the seedling pot 21. Since the locus K from the position K1 to the position K2 is linear, the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R recede straight from the seedling pot 21. At this time, the force in the direction approaching each other acts on the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R by the restoring force of the tension spring 263, and the seedlings 22 extracted from the seedling pot 21 are held. I can do it. The opening / closing operation of the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R will be described later together with the operation of the push rod 281.

  The movement of the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R from the position K6 toward the position K1 is performed with respect to the seedlings 22 in the breeding pot 21 of the tray 20 at the seedling extraction position. 261L, 261R is inserted, and moves in the opposite direction along the path K from the position K1 to the position K2, so that the tips 261Lp, 261Rp of the pair of extraction claws 261L, 261R It is inserted almost straight into the pot 21. At this time, the force in the direction away from each other acts against the restoring force of the tension spring 263 on the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R, and both the tip portions are open. You can enter the seedling pot 21.

  Thus, the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R do not damage the tray 20, the seedling pot 21, and the seedling itself.

  The trajectory K from the position K1 to the position K2 and the trajectory K from the position K6 to the position K1 are substantially linear. The side near the tray supply device 100 of the guide groove 241 is linear. It is because it is done.

  Next, as moving from the position K2 to the position K3, the tip portions 261Lp and 261Rp of the pair of take-out claws 261L and 261R change their postures from the posture facing the seedling pot 21 until then substantially downward. When moved to the position K4, the tip portions 261Lp and 261Rp are substantially directed downward.

  The reason why the posture is suddenly changed substantially downward as described above is that the side of the guide groove 241 far from the tray supply device 100 is formed in a shape that rises in a substantially R shape.

  At that time, just below the tip portions 261Lp and 261Rp, the seedling insertion port (not shown) of the planting device 7 in the ascending process on the locus T1 (see FIG. 1) is directed upward toward the top dead center. The seedling 22 pushed out from the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R by the push rod 281 falls to the seedling inlet of the planting device 7 between the position K4 and the position K5. Supplied to the planting tool 11. The operation of the push rod 281 will be further described later.

  Next, from the position K5 toward the position K6, the tip portions 261Lp and 261Rp of the pair of take-out claws 261L and 261R abruptly move so that the posture that has been directed substantially downward until then can be opposed to the next seedling pot 21. The tip portions 261Lp and 261Rp are inserted into the new seedling pot 21 when the position is changed to move to the position K1.

  As can be seen from the approximate correspondence between the rotation position of the drive arm 220 and the position on the locus K of the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R shown in FIG. 9, the position K4 to the position K5 Since the movement toward is performed more slowly than the movement from the position K1 to the position K2 described above, the removal of the seedling 22 from the seedling pot 21 can be performed quickly and the release of the seedling 22 to the planting device 7 is ensured. Can be done.

  Such an operation is performed because the connecting arm 230 is provided in front of the drive arm 220 (the extraction position of the tray supply device 100). Further, since the drive arm 220 is farther from the extraction position of the tray supply device 100 than the connection arm 230, it does not come into contact with the seedling 22 when the seedling 22 is taken out.

  Next, the operation of the transmission mechanism 290 and the extrusion mechanism 280 will be mainly described with reference to FIGS.

  As shown in FIG. 7, the first gear 291 fixed to the distal end side portion 220 a of the drive arm 220 by the rotation of the drive arm 220 in the B direction moves in the B direction around the rotation fulcrum 220 b of the drive arm 220. Revolve. The first gear 291 is rotatably attached to the connecting arm 230 via the first rotation shaft 291a, and rotates the third gear 293 in the B direction via the second gear 292. The third gear 293 is fixed to the distal end portion 245 b of the first guided member 245 that is integral with the cam shaft 271, and the edge portion 245 a near the distal end of the first guided member 245 is connected to the connecting arm 230. Since the third gear 293 rotates, the cam 270 rotates in the B direction via the cam shaft 271. That is, the cam 270 rotates in accordance with the drive cycle of the drive arm 220.

  The cam 270 has an outer peripheral portion 272 whose thickness varies depending on the location, and an outermost edge portion 273 whose distance (outer diameter) from the center of the cam shaft 271 varies depending on the location. As shown, the protruding portion 273b in the outermost edge portion 273 has a larger outer diameter than the other portion 273a, and the thickness of the first range 272a is within the outer peripheral portion 272 at the same distance from the axial center of the cam shaft 271. The thickness is set smaller than the thickness of the second range 272b which is the remaining thick portion.

  With the above configuration, when the cam 270 rotates in synchronization with the drive cycle of the drive arm 220, the distal ends 261Lp and 261Rp of the pair of extraction claws 261L and 261R move from the position K6 to the position K1. The opening / closing operation of the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R and the operation of the push rod 281 are as follows.

  That is, the second range 272b, which is a thick portion of the outer peripheral portion 272 of the cam 270, comes into contact with the tip surfaces of the pair of left and right claw tip width restricting projections 262L and 262R, whereby a pair of extraction claws 261L and 261R The front end portions 261Lp and 261Rp are opposed to the restoring force of the tension spring 263, and force in directions away from each other is acting, and both the front end portions are open.

  On the other hand, at this time, the protrusion 273b of the outermost edge 273 of the cam 270 is in contact with the outer peripheral edge of the base portion of the first projection 283c for holding the tension spring, so that the push arm tension spring 284 is pulled. The push-out arm 283 is rotated counterclockwise in FIG. 8 (see arrow C), and the push-out rod 281 connected by the connecting rod 282 is maintained in the retracted state.

  Therefore, the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R can enter the seedling raising pot 21 and take out the seedling.

  Next, the opening / closing operation of the pair of extraction claws 261L, 261R, 261Lp, 261Rp when the tip portions 261Lp, 261Rp of the pair of extraction claws 261L, 261R perform the operation from the position K1 toward the position K2, and the extrusion The operation of the rod 281 is as follows.

  That is, at the same time when the operation from the position K1 toward the position K2 is started, the first range 272a, which is a thin portion of the outer peripheral portion 272 of the cam 270, is connected to the tip surfaces of the pair of left and right claw tip width regulating projections 262L and 262R. By making contact, the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R move toward each other due to the restoring force of the tension spring 263, so that both tip portions are closed.

  On the other hand, at this time, the protrusion 273b of the outermost edge 273 of the cam 270 is still in contact with the outer peripheral edge of the base portion of the first projection 283c for holding the tension spring, so that the push-out arm tension spring 284 is The pusher arm 283 is stretched and maintains the state of rotating counterclockwise in FIG. 8 (see arrow C), and the pusher rod 281 connected by the connecting rod 282 is maintained in the retracted state. Yes.

  Therefore, the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R can hold the extracted seedling 22 firmly at the tip portion and move to the planting device 7 side as it is.

  Next, the opening / closing operation of the pair of extraction claws 261L, 261R, 261Lp, 261Rp when the tip portions 261Lp, 261Rp of the pair of extraction claws 261L, 261R perform the operation from the position K4 toward the position K5, and extrusion The operation of the rod 281 is as follows.

  That is, at the same time when the operation from the position K4 toward the position K5 is started, the other portion 273a of the outermost edge portion 273 of the cam 270 is replaced with the outer peripheral edge of the root portion of the first protrusion 283c for holding the tension spring. 8, the pushing arm 283 is instantaneously rotated clockwise in FIG. 8 by the restoring force of the pushing arm tension spring 284 (see arrow D), and the pushing arms connected by the connecting rod 282. At the same time as the rod 281 is pushed out, the cutout part 281b of the tip part 281a of the push rod 281 moves while expanding the tip parts of the pair of extraction claws 261L, 261R.

  Thereby, the seedling 22 pushed out from the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R by the tip portion 281a of the extrusion rod 281 falls to the seedling inlet of the planting device 7 and is supplied to the planting tool 11 Is done. At this time, the cutout portion 281b of the distal end portion 281a of the push rod 281 moves while pushing and expanding the distal end portions of the pair of extraction claws 261L and 261R, so that the dirt or the like attached to the distal end portion is simultaneously removed. It is.

  Next, the opening / closing operation of the pair of extraction claws 261L, 261R, 261Lp, 261Rp when the tip portions 261Lp, 261Rp of the pair of extraction claws 261L, 261R perform the operation from the position K5 to the position K6, and extrusion The operation of the rod 281 is as follows.

  That is, in the outer peripheral portion 272 of the cam 270, the second range 272b which is a thick portion instead of the first range 272a which is a thin portion is in contact with the tip surfaces of the pair of left and right claw tip width regulating projections 262L and 262R. By doing so, the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R change to a state in which both tip portions are opened due to the force in the direction away from each other against the restoring force of the tension spring 263. To do.

  On the other hand, when coming to the vicinity of the position K6, the projecting portion 273b of the outermost edge portion 273 of the cam 270 contacts the outer peripheral edge portion of the base portion of the first projection 283c for holding the spring spring instead of the other portion 273a. As a result, the push arm tension spring 284 is extended, the push arm 283 is swung counterclockwise in FIG. 8 (see arrow C), and the push rod 281 connected by the connecting rod 282 is retracted. Change to state.

  In the above-described embodiment, the case where the pair of extraction claws 261L and 261R are integrally formed of the same metal plate member from the root portion to the distal end portion has been described. About the front end side, it may be made of, for example, a rubber plate or a resin plate that can be detached and has elasticity. Thereby, even if the tip part grasps the seedling 22 by the restoring force of the tension spring 263, the rubber plate is deformed by the elasticity of the tip side, so that the seedling 22 is not crushed.

  Further, the push rod 281 covers the upper ends of the pair of extraction claws 261L and 261R until the distal ends 261Lp and 261Rp of the pair of extraction claws 261L and 261R move in the vicinity of the position K6. Although configured, this can prevent the leaves of the seedling 22 on the tray 20 from being caught by the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R when moving from the position K5 to the position K6.

  In addition, the push rod 281 is configured to be retracted in accordance with the insertion speed when the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R are inserted into the seedling pot 21, thereby the leaves of the seedling 22 Can be prevented from being entangled with the tip portions 261Lp and 261Rp.

  Next, with reference to FIGS. 5 and 6 again, the mechanism for intermittently driving the tray feed rod 121 of the tray supply apparatus 100 will be further described.

  As shown in FIG. 6, the tray vertical feeding device 120 has (1) the above-described tray feeding rod 121 and (2) the upper end portion 121b1 of the both ends 121b of the tray feeding rod 121 fixed, and one of them bent inward. A feed rod arm 130 having a projecting cam 131 having a curved edge portion 131a formed at the lower portion, and (3) a root portion 141 is rotatably supported by the side plate 110a of the seedling table 110, and a feed rod at the tip portion 142. A feed arm 140 that rotatably supports the arm 130 and has a first recess 143a, a second protrusion 143b, and a third recess 143c formed smoothly and continuously in a side view at the lower edge, and (4) a seedling The longitudinal feed pivot shaft 151 that pivots in the direction of arrow E by the driving force obtained from the power source of the transplanter 1 is viewed from the side of the take-out device 200, and is located at two locations, the center position and the right end position of the longitudinal feed pivot shaft 151. Respectively fixed, provided with a longitudinal feeding drive arm 150 having a restraining roller 152 rotatably to the tip portion.

  Further, a feed arm tension spring 160 is attached between the front end portion 142 of the feed arm 140 and the lower portion 110a1 of the side plate 110a of the seedling table 110 so that a downward pulling force is always applied to the feed arm 140. ing. Further, a spring mounting rod 163 that holds the other end of the feed rod arm tension spring 161 having one end attached to the pin 132 attached to the upper end portion of the feed rod arm 130 is fixed to the root portion 141 of the feed arm 140. Has been.

  Next, the intermittent operation of the tray feed rod 121 will be described with reference to FIGS.

  It is assumed that the seedling table 110 is moved in the right direction, that is, in the direction of arrow F (see FIG. 5) by the rotation of the lead cam shaft 171. At that time, the longitudinal feed rotation shaft 151 is rotated in the direction of arrow E (see FIG. 6).

  In the meantime, the take-out device 200 sequentially takes out the seedlings 22 from the seedling pot 21 at the right end and supplies the seedlings 22 to the planting device 7, and then the leftmost end when the seedling placement stand 110 moves to the rightmost end. The seedling 22 of the nursery pot 21 is taken out by the take-out device 200. Thereby, all the seedlings 22 for one horizontal row of the seedling pot 21 are taken out.

  At this time, it is rotatably attached to the front end portion of the vertical feed drive arm 150 which is rotated in the direction of arrow E together with the vertical feed rotary shaft 151 and which is fixed to the right end of the vertical feed rotary shaft 151. Since the check roller 152 is configured to start contact with the curved edge portion 131a of the feed rod arm 130 after a short delay after the contact with the first recess 143a of the feed arm 140 is started, the tray feed rod 121 is After the feed arm 140 has once moved upward with the clockwise rotation of the feed arm 140, it starts to rotate counterclockwise around the axis of the tip end portion 142.

  That is, when the tray feed rod 121 is once moved upward in the direction of the arrow 121a0 (see FIGS. 5B and 6), the protrusion 121ab of the tray feed rod 121 that has been held by the notch 112a until then. However, the center portion 121a of the tray feed rod 121 that has been waiting in the gap 21a on the back side of the seedling pot 21 is also moved upward in the direction of the arrow 121a0 within the range of the gap 21a. . Thereafter, the feed rod arm 130 starts to rotate counterclockwise about the axis of the tip end portion 142, whereby the central portion 121a of the tray feed rod 121 moves in the direction of the arrow 121a1 (see FIG. 6). In addition, the notch depth of the notch part 112a is set to such an extent that the center part 121a of the tray feed rod 121 can move within the range of the gap 21a.

  Thereafter, when the check roller 152 continues to rotate, the check roller 152 continues to contact the curved edge portion 131a of the feed rod arm 130, so that the central portion 121a of the tray feed rod 121 is positioned in the retreat groove 111a. Maintained. At this time, the check roller 152 simultaneously moves from the first concave portion 143a of the feed arm 140 toward the second convex portion 143b, so that the feed arm 140 further rotates clockwise, and the central portion 121a of the tray feed rod 121 is As a result, it moves in the direction of the arrow 121a2 (see FIG. 6) while maintaining the state of being located in the retreat groove 111a.

  Thereafter, when the check roller 152 continues to rotate, the check roller 152 is not in contact with the curved edge portion 131a of the feed rod arm 130, and at the same time, the feed rod arm 130 is moved by the restoring force of the feed rod arm tension spring 161. The central portion 121a of the tray feed rod 121 is instantaneously rotated clockwise about the axis of the tip portion 142, so that the arrow 121a3 is directed from the gap 21a toward the gap 21b located on the upper side by one row of the seedling pot 21. Move as shown in.

  Thereafter, when the check roller 152 continues to rotate, the check roller 152 moves while being in contact with the third recess 143 c of the feed arm 140, so that the feed arm 140 is moved downward by the restoring force of the feed arm tension spring 160. As a result, the central portion 121a of the tray feed rod 121 moves in the direction of the arrow 121a4 (see FIG. 6) while maintaining the state of being located in the gap 21b. The protrusion 121ab of 121a is held by the notch 112a.

  And the center part 121a of the tray feed rod 121 moved in the direction of the arrow 121a4 (see FIG. 6) maintains the state of being positioned in the gap between the seedling pots on the back side of the seedling pot 21, and the seedling stand 110 is When the movement starts in the arrow G direction, that is, the left direction, the takeout device 200 sequentially takes out the seedlings 22 from the seedling pot 21 at the left end and supplies the seedlings 22 to the planting device 7. The seedling 22 of the rightmost breeding pot 21 is taken out by the take-out device 200 at the time of moving to. Thereby, all the seedlings 22 for one horizontal row of the seedling pot 21 are taken out.

  During this time, the projection 121ab of the central portion 121a of the tray feed rod 121 is held by the notch 112a, so that the tray 20 moves downward due to the weight of the seedling 22 placed in the seedling pot 21. Can be prevented.

  In addition, when all the seedlings 22 for one horizontal row of the seedling pot 21 are taken out, unlike the above, it can be freely rotated at the front end portion of the vertical feed driving arm 150 fixed to the center position of the vertical feed rotary shaft 151. The attached check roller 152 starts contact between the curved edge 131a of the feed rod arm 130 and the first recess 143a of the feed arm 140.

  By repeating the above-described operation, the tray 20 is moved rightward or leftward, and is intermittently vertically fed by one row of the seedling pot 21.

  Thereby, the tray vertical feeding device 120 having a compact structure is obtained. Further, the tray conveyance path 111 can be supported so as to be movable left and right with a simple structure of the guide rail 155 and the lead cam shaft 171.

  Further, since the central portion 121a of the tray feed rod 121 is disposed on the flat surface portion 111b of the tray conveying path 111, the tray 20 does not bend inward, so that a gap with a certain width is provided on the back side of the seedling pot 21. Since 21a and 21b can be secured, the tray feed rod 121 can surely enter the gaps 21a and 21b.

  Further, since the curved surface portion 111c is provided on the downstream side of the flat surface portion 111b of the tray conveyance path 111, the tray 20 bends along the curved surface. Therefore, even when the tray feed rod 121 is moving in the direction of the arrow 121a2 during tray feeding, the bending becomes resistance, and the tray 20 is prevented from shifting to the downstream side.

  Next, the seedling planting device 300 and the seedling planting device driving mechanism 400 described above will be further described with reference to FIGS. 10 and 11.

  FIG. 10 is a left side view of the seedling planting device 300 and the seedling planting device driving mechanism 400. FIG. 11 is a schematic left side view of the seedling planting device drive mechanism 400.

  As shown in FIG. 10, the seedling planting apparatus 300 includes a planting tool 11 for planting the seedling 22 in a field, an upper arm 311 and a lower arm arranged in parallel with each other for swinging the planting tool 11 in the vertical direction. A swing link mechanism 310 having an arm 312 and a vertically moving arm 320 that is rotatably attached to the lower arm 312 via a first connecting shaft 321 and moves the swing link mechanism 310 up and down are provided. The first connecting shaft 321 is fixed to the vertical movement arm 320.

  In addition, the vertical movement arm drive shaft 440 for rotating the vertical movement arm 320 is provided so as to protrude from the seedling planting device drive mechanism 400, and the vertical movement arm 320 is fixed to the tip portion thereof.

  Further, as shown in FIG. 10, the seedling planting device 300 is rotatably attached to the lower arm 312 via the second connection shaft 341 and opens and closes the planting tool 11, and the first connection shaft 321. And is rotated around the second connecting shaft 341 while being in contact with the outer peripheral edge of an opening / closing roller 342 that is pivotably attached to the tip of the opening / closing arm 340 via the third connecting shaft 343. Thus, the opening / closing cam 322 that swings the opening / closing arm 340 in the front-rear direction, one end 351 is connected to the third connection shaft 343 at the tip of the opening / closing arm 340, and the other end 352 is the opening / closing mechanism of the planting tool 11. And an open / close connection cable 350 connected to the 11a side.

  Here, the swing link mechanism 310 described above will be further described.

  That is, as shown in FIG. 10, the swing link mechanism 310 is supported by the front upper end portion 401a of the casing 401 housing the seedling planting device drive mechanism 400 so that the upper end is rotatably supported by the upper front shaft 313a, and the lower end is A front swing arm 316a that is rotatably connected to a connection support plate 315 via a lower front shaft 314a, and a rear upper end portion 401b that houses a seedling planting device drive mechanism 400, an upper end is an upper rear portion. An upper shaft provided on the connection support plate 315, having a rear swing arm 316b supported rotatably on the shaft 313b and having a lower end rotatably connected to the connection support plate 315 via the lower rear shaft 314b. The front end of the upper arm 311 described above is rotatably connected to 316, and the front end of the lower arm 312 described above is rotatably connected to the lower rear shaft 314b of the connection support plate 315. Each of the rear end of the upper arm 311 and lower arm 312 is pivotally connected to the rotating upper shaft 317a and the rotation under shaft 317b provided on the support plate 317 of the planting device 11.

  The seedling 22 of the present embodiment is an example of the transplant of the present invention, and the swing link mechanism 310 is an example of the swing link mechanism of the present invention.

  With the above configuration, when the rotational driving force is transmitted to the vertical movement arm drive shaft 440 in the seedling planting device drive mechanism 400, the vertical movement arm 320 fixed to the vertical movement arm drive shaft 440 rotates in the direction of the arrow A1. By moving, the lower arm 312 and the upper arm 311 repeatedly swing up and down and swing back and forth, so that the planting operation of the seedling 22 by the planting tool 11 is performed with respect to the ridge U. Automatically done at intervals.

  Further, when the vertical movement arm 320 to which the first connecting shaft 321 is fixed rotates in the direction of arrow A1 during the planting operation, the opening / closing cam 322 fixed to the first connecting shaft 321 becomes the opening / closing roller. Since it rotates while contacting the outer peripheral edge of 342, the open / close arm 340 swings (rotates) forward (counterclockwise) about the second connecting shaft 341. Along with this operation, one end 351 of the open / close connection cable 350 is pulled in the forward direction, so that the open / close mechanism 11a operates to open the planting tool 11.

  Further, when the open / close arm 340 swings (rotates) backward (clockwise) about the second connecting shaft 341, the planting tool 11 provided in the open / close mechanism 11a is always biased in the closing direction. The one end 351 of the opening / closing connection cable 350 is pulled rearward by the action of a spring (not shown), so that the opening / closing mechanism 11 a operates to close the planting tool 11.

  With the above configuration, since the vertical movement arm 320 is driven by one axis, the structure is simple, and the vertical movement arm 320, the opening / closing arm 340, and the opening / closing cam 322 can be configured compactly, and the planting operation can be performed smoothly.

  Next, a clutch mechanism for turning on and off the transmission to the vertical movement arm drive shaft 440 in the seedling planting device drive mechanism 400 arranged on the right side of the seedling planting device 300 in plan view (see FIG. 2) will be mainly described with reference to FIG. This will be further described using.

  As shown in FIG. 11, the seedling planting device drive mechanism 400 includes a first gear 410 and a first gear 410 for transmitting the planting driving force output from the planting transmission device 18 to the planting clutch 420. When the planting clutch 420 and the planting clutch 420 are in the “ON” state, the transmission to the vertical movement arm drive shaft 440 is switched to the “ON” state or “OFF” state. A second gear 430 receiving a driving force from a transmission gear 421a fixed to the transmission shaft 421 of the planting clutch 420, and a small-diameter gear 430a fixed coaxially with the second gear 430. The third gear 450 fixed to the vertical movement arm drive shaft 440 is rotatably arranged so as to be engaged with the vertical movement arm drive shaft 440. Here, when the planting clutch 420 is in the “disengaged” state, the transmission shaft 421 of the planting clutch 420 stops without rotating and does not transmit the driving force to the second gear 430.

  In addition, you may use the conventional fixed position stop clutch as the planting clutch 420 of this Embodiment.

  Further, as shown in FIG. 11, the seedling planting device drive mechanism 400 is provided on the transmission downstream side of the planting clutch 420 and is fixed to the vertical movement arm drive shaft 440, and the planting clutch 420 is moved from the “entered” state. Depending on whether the intermittent cam 441 having a concave portion 441a formed in a part of a circular outer peripheral edge for forcedly switching to the “cut” state and the one end portion 460a are separated from or in contact with the planting clutch 420 The first arm 460 having a substantially “h” shape in a side view, which is pivotally supported by a pivotal fulcrum 461, for switching between the engaged state and the disengaged state of the planting clutch 420. I have.

  Further, as shown in FIG. 11, the seedling planting device drive mechanism 400 sucks the other end 460 b of the first arm 460 in the direction of arrow B <b> 1 through the movable plate 472 against the pulling force of the tension spring 480. Thus, the solenoid 470 that rotates the one end portion 460a of the first arm 460 around the rotation fulcrum 461 in the direction of the arrow C1 to switch the planting clutch 420 from the “disengaged” state to the “entered” state. In addition, a mounting adjustment long hole 471a capable of adjusting the mounting position of the solenoid 470 is provided so that the suction force of the solenoid 470 effectively acts on the switching operation of the planting clutch 420 to the “ON” state. , A solenoid fixing plate 471 fixed at a lower position of the casing 401, and one end portion 462 at the rotation fulcrum 461 of the first arm 460. There are fixed, the other end portion in conjunction with the operation of the first arm 460 462b is provided with a second arm 462 that abuts the outer peripheral edge portion of the intermittent cam 441, a.

  Further, the above-described tension spring 480 presses the first arm 460 in the direction in which the planting clutch 420 is in the “disengaged” state and the other end 462b of the second arm 462 against the outer peripheral edge of the intermittent cam 441. A spring for biasing in the direction.

  According to the above configuration, the intermittent clutch 441 provided on the downstream side of the transmission of the planting clutch 420 can be used to change the planting clutch 420 from the “on” state to the “disconnected” state. A planting mechanism can be realized.

  Further, the first arm 460 and the second arm 462 are configured to rotate integrally around the rotation fulcrum 461, and the rotation fulcrum 461 is more intermittent than the transmission shaft 421 of the planting clutch 420. By arranging on the side, the first arm 460 and the second arm 462 can be rational and compact.

  In addition, by arranging the solenoid 470, which is a heavy object, below the casing 401, the center of gravity of the seedling transplanter 1 can be lowered.

  Next, with reference to FIG. 11, the items A to B are centered on the operation of the planting clutch 420 and the intermittent cam 441 for turning on and off the transmission to the vertical movement arm drive shaft 440 in the seedling planting device drive mechanism 400. Each of the three scenes of C will be explained.

  A. When the solenoid 470 is energized (a short time energization by a pulse signal), the movable plate 472 at the tip of the solenoid 470 is attracted in the direction of the arrow B1 against the pulling force of the tension spring 480, and the first arm 460 is drawn. One end portion 460a of the second arm 462 and the other end portion 462b of the second arm 462 rotate counterclockwise (refer to the arrow C1 in FIG. 11) about the rotation fulcrum 461.

  Thus, the following operations i) and ii) are performed when the one end 460a of the first arm 460 is separated from the planting clutch 420.

  i) When the planting clutch 420 is in the “engaged” state and the transmission shaft 421 rotates, a driving force is transmitted to the second gear 430 side, and the vertical movement arm drive shaft 440 is transmitted via the third gear 450. Ii) the other end 462b of the second arm 462 moves away from the recess 441a formed in the outer peripheral edge of the intermittent cam 441 (until this time, the other end 462b of the second arm 462). Is located in the recess 441a of the intermittent cam 441, and the planting clutch 420 is in the “disengaged” state, and the vertical movement arm drive shaft 440 stops rotating), along the convex outer peripheral edge 441b. However, the intermittent cam 441 and the vertical movement arm 320 continue to rotate.

  That is, the energization to the solenoid 470 has already been stopped and the suction force to the arrow B1 is not generated, but the other end 462b of the second arm 462 is connected to the convex outer peripheral edge 441b of the intermittent cam 441. Since the one end portion 460a of the first arm 460 is away from the planting clutch 420 while the along state is maintained, the planting clutch 420 can maintain the “on” state and move up and down. The planting tool 11 (see FIG. 10) continues to move up and down (planting operation) by the rotation of the arm 320, and the planting tool 11 is planted only once until the intermittent cam 441 rotates once. Perform the action.

  B. Thereafter, when the intermittent cam 441 makes one rotation and the other end 462b of the second arm 462 reaches the recess 441a of the intermittent cam 441, the first arm 460 rotates clockwise by the tensile force of the tension spring 480. When the first arm 460 is in contact with the planting clutch 420, the following i) and ii) are performed.

  i) The planting clutch 420 is in a “disengaged” state, and the rotation of the transmission shaft 421 stops, so that the driving force is not transmitted to the second gear 430 side, so the vertical arm drive shaft 440 stops rotating. And ii) the other end 462b of the second arm 462 remains in the recess 441a formed on the outer peripheral edge of the intermittent cam 441 (until this time, the other end 462b of the second arm 462 is used for intermittent use. The planting clutch 420 is in the “engaged” state along the convex outer peripheral edge 441b of the cam 441, and the vertical movement arm drive shaft 440 continues to rotate)), the intermittent cam 441 and the vertical movement arm 320. Since the rotation continues to stop, the planting tool 11 (see FIG. 10) continues to stop the vertical movement (planting operation).

  C. Thereafter, when the solenoid 470 is energized at an arbitrary timing, the planting clutch 420 enters the “engaged” state, and the operation described in item A above is started.

  According to the said structure, the time which the vertical movement (planting operation | movement) of the planting tool 11 has stopped can be adjusted by controlling the said arbitrary timing which supplies with electricity to the solenoid 470. FIG. Thereby, intermittent planting is possible with a simple configuration.

  Next, the various operation levers and the operation unit 600 that are disposed in the vicinity of the pair of left and right handle grips 8L and 8R of the steering handle 8 will be described with reference to FIG. FIG. 12 is a plan view for explaining various operation levers and the operation unit 600 arranged in the vicinity of the pair of left and right handle grips 8L and 8R of the steering handle 8. FIG.

  As shown in FIG. 12, a main clutch lever 80 is provided in the vicinity of the left handle grip 8L of the steering handle 8, and an elevating operation lever 81 for operating the hydraulic elevating cylinder 10 is provided in the vicinity of the right handle grip 8R. Is provided.

  The raising / lowering operation lever 81 is configured to be manually switchable in three stages of “lowering”, “neutral”, and “raising”, and when switched to the “lowering” position, the hydraulic lifting cylinder 10 is to lower the traveling vehicle body 15. When the operation is stopped and the lowering is stopped by a sensor plate 710 (see FIG. 13), which will be described later, and the planting on / off button 620 (see FIG. 12), which will be described later, is in an ON state, the planting clutch 420 enters an “on” state. Planting work is started.

  When the lifting operation lever 81 is switched to the “neutral” position, the planting operation is stopped. When the lifting operation lever 81 is switched to the “raised” position, the hydraulic lifting cylinder 10 operates to raise the traveling vehicle body 15.

  Also, as shown in FIG. 12, the operation panel 601 has, in order from the left end to the right end, (1) an empty planting operation button for operating only the planting tool 11 in a state in which the traveling of the traveling vehicle body 15 is stopped. 610, and (2) when the lifting operation lever 81 is operated to the lowering operation position for lowering the traveling vehicle body 15, the planting tool 11 is operated in conjunction with the lowering operation, and is not interlocked with the lowering operation. A planting on / off button 620 that switches to any one of the states, (3) a display unit 630 that displays at least between planted strains, and (4) an adjustment button 640 that adjusts at least between planted strains are arranged.

  With the above configuration, the planting on / off button 620 is arranged near the center of the operation panel 601, and thus it is easy to operate.

  Moreover, since the sky planting operation button 610 is disposed on the left side of the rear surface 601b different from the upper surface 601a on which other operation buttons are disposed, erroneous operations by the operator can be reduced.

  Further, since the display unit 630 is disposed near the center of the operation panel 601, it is easy to confirm.

  The adjustment button 640 includes an “up” push switch 640 a that changes the stock in the direction of expanding the stock, and a “down” push switch 640 b that changes in the direction of narrowing the stock on the lower side.

  With the above configuration, by operating the “raising” push switch 640a and the “lowering” push switch 640b, the numerical value indicating between stocks is directly displayed on the display unit 630, so that an operator can easily recognize between stocks.

  Next, referring mainly to FIGS. 13 and 14, a solenoid 470 for performing planting on / off based on operations of the planting depth adjusting mechanism 700, the planting on / off button 620, the lifting operation lever 81, and the like. The control unit 800 that controls the operation will be mainly described.

  FIG. 13 is a left side view illustrating a schematic configuration of the planting depth adjusting mechanism 700, and FIG. 14 is a schematic configuration diagram illustrating input and output to the control unit 800.

  As shown in FIG. 13, the planting depth adjusting mechanism 700 includes: (1) a sensor plate 710 having a gently curved bottom surface that maintains a constant planting depth by contacting the farm scene 701; ) A substantially L-shaped plate-like member in a side view, wherein an L-shaped bent portion is rotatably supported with respect to the traveling vehicle body 15 by a rotation support shaft 721, and one end 722 extending rearward is a sensor plate. The other end 723 that is pivotally connected to the front end 711 of the 710 and the pivot support shaft 722a and that extends upward is manually operated by an operator in the vertical (up and down) direction of the sensor plate 710. A depth arm 720 that is pivotably connected to the distal end portion 741 of the transmission rod 740 that transmits the movement of the depth lever 730 for setting the position; and (3) the depth arm 720 is swingable from the main frame 17. A hanging spring 750, (4) It is a substantially L-shaped plate-like member in a plan view, and an L-shaped bent portion is rotatably supported with respect to the traveling vehicle body 15 by a rotation support shaft 761, and a long hole is formed below the rotation support shaft 761. 762 is formed, and is urged by the tension spring 766 connected to the upper end portion 763 to rotate in the arrow Y direction with the rotation support shaft 761 as an axis, and is provided in the hydraulic pressure switching valve portion 40. A counter arm 760 having a front end portion 764 connected by a rod 765 with respect to a lift operation valve (not shown), and (5) a counter arm 771 is positioned so that the front end side of the elongated hole 762 of the counter arm 760 is positioned. A planting switch 770 disposed on the arm 760, and (6) a connecting pin 781a provided at one end 781 is inserted into the elongated hole 762, and the other end 782 is connected via a connecting shaft 783. The upper end 712 and rotatably coupled to a sensor rod 780 of capacitors plate 710, and a.

  Further, the sensor rod 780 is interlocked with the swing in the arrow Z direction of the upper end 712 of the sensor plate 710 by the upward swing of the sensor plate 710, so that the front end edge portion 781b of the one end 781 is turned on and off. It moves to the direction which pushes the detection lever 771, and is the structure which turns on the planting switch 770.

  According to the above configuration, since the depth arm 720 is suspended by the spring 750, rattling of the connecting portion between the depth arm 720 and the depth lever 730 is eliminated, and the depth set by the depth lever 730 is stable. To do. The spring 750 is configured to suspend the depth arm 720, but is not limited thereto, and may be configured to press the depth arm 720 against the main frame side, for example.

  Further, according to the above configuration, the counter arm 760 is pulled by the tension spring 766 in the direction of pushing down the sensor plate 710, so that the backlash between the sensor rod 780 and the counter arm 760 can be eliminated.

  Further, by changing the elastic force of the tension spring 766, the force pushing the sensor plate 710 can be changed.

  Next, a method of controlling the solenoid 470 by the control unit 800 provided below the operation panel 601 will be described with reference to FIG.

  As shown in FIG. 14, the control unit 800 receives at least an on / off signal from the planting on / off button 620, a switching signal for the lifting operation lever 81, and an on / off signal from the planting switch 770. The pulse signal is output to the solenoid 470.

  Based on the above configuration, the operation of the control unit 800 will be mainly described with reference to FIGS.

  Here, after moving the seedling transplanter 1 to a predetermined position in the field, (1) a scene where the planting operation is to be started, and then (2) a scene where the planter is traveling while planting in the field, and (3) The explanation will be divided into scenes that come to the edge of the kite and turn.

(1) Scenes where planting work is about to start:
When the seedling transplanter 1 is moved to a predetermined position in the field, the planting on / off button 620 is set to the “on” state, and the lifting operation lever 81 is set to the “up” position. Is in a high position.

  When the operator operates the elevating operation lever 81 to the “lower” position to lower the vehicle height of the traveling vehicle body 15, the sensor plate 710 is lowered together with the traveling vehicle body 15 toward the farm scene 701.

  When the sensor plate 710 comes into contact with the farm scene 701, the front end 711 of the sensor plate 710 rotates in the arrow Z direction, so that the front end edge 781b of the sensor rod 780 moves in the direction of pushing the on / off detection lever 771 and is planted. By turning on the switch 770, an ON signal from the planting switch 770 is input to the control unit 800.

  The control unit 800 outputs a signal indicating the “ON” state from the planting on / off button 620, a signal indicating the “down” position from the lifting operation lever 81, and an “ON” signal from the planting switch 770 under AND conditions. In response to this, a signal for energizing the solenoid 470 is output.

  Thereby, the planting clutch 420 is switched from the “cut” state to the “on” state, and the planting operation is started.

(2) Scene of traveling while planting in the field:
Here, it is assumed that the raising / lowering operation lever 81 is in the “down” position, and the sensor plate 710 moves up and down according to the unevenness of the farm scene 701.

  In addition, the control unit 800 outputs a pulse signal at the operation cycle so that the solenoid 470 is energized at a predetermined operation cycle. Accordingly, the planting clutch 420 enters the “ON” state when the solenoid 470 is energized, and the intermittent cam 441 starts to rotate and completes one rotation (that is, the seedling planting operation is performed once). When finished, a series of operations of returning to the “off” state is repeated in the operation cycle.

  Thereby, a planting operation | work is performed intermittently and desired planting stock | strain is implement | achieved.

  In response to the vertical movement of the sensor plate 710, the hydraulic lifting cylinder 10 operates as follows.

  That is, when the sensor plate 710 moves upward, the front end 711 of the sensor plate 710 moves in the direction of the arrow Z around the rotation support shaft 722a, and the connecting pin 781a provided at one end 781 of the sensor rod 780 When moving in the direction of pushing the front edge of the long hole 762, the counter arm 760 rotates in the clockwise direction in FIG. 13 with the rotation support shaft 761 as the axis, and this movement via the rod 765 causes the hydraulic pressure switching valve. It is transmitted to an elevating operation valve (not shown) provided in the section 40 and is operated in the direction in which the hydraulic elevating cylinder 10 extends, and the vehicle height of the traveling vehicle body 15 is increased.

  On the other hand, when the sensor plate 710 moves downward, the front end portion 711 of the sensor plate 710 moves in the direction opposite to the arrow Z direction around the rotation support shaft 722a and is connected to one end portion 781 of the sensor rod 780. When the pin 781a moves in a direction away from the front edge portion of the long hole 762, the counter arm 760 rotates in the arrow Y direction with the rotation support shaft 761 as the axis by the pulling force of the tension spring 766, and this movement is the rod 765. Is transmitted to a lifting operation valve (not shown) provided in the hydraulic pressure switching valve portion 40, and the hydraulic lifting cylinder 10 is operated in a shorter direction, and the vehicle height of the traveling vehicle body 15 is lowered.

  By the above operation, even if the farm scene 701 is uneven, the planting depth of the seedling can be kept constant.

(3) A scene of turning to the edge of the kite:
In this scene, the operator moves the lifting operation lever 81 from the “lower” position to the “neutral” position in order to interrupt the planting operation.

  Accordingly, the control unit 800 receives the signal indicating the “neutral” position from the elevating operation lever 81 and stops outputting the pulse signal to the solenoid 470. Thus, after the planting clutch 420 is switched from the “ON” state to the “OFF” state, the “OFF” state is continuously maintained, so that the planting operation is interrupted.

  Further, the operator moves the lifting / lowering operation lever 81 from the “neutral” position to the “raised” position in order to turn the traveling vehicle body 15 toward the adjacent saddle.

  In conjunction with the movement of the cable 82 in response to the operation of the elevating operation lever 81, the elevating operation valve (not shown) provided in the hydraulic pressure switching valve unit 40 is operated, and the hydraulic elevating cylinder 10 moves in the extending direction. As a result, the vehicle height of the traveling vehicle body 15 increases.

  At this time, the sensor plate 710 is lowered and the planting switch 770 is turned off, but no signal is output from the control unit 800.

  The planting clutch 420 is maintained in the “disengaged” state, and the state where the planting operation is interrupted is continued.

  Therefore, the worker turns the traveling vehicle body 15.

  Next, when the operator moves the elevating operation lever 81 from the “raised” position to the “lowered” position through the “neutral” position, the hydraulic pressure is moved in conjunction with the movement of the cable 82 according to the operation of the elevating operation lever 81. When the lifting operation valve provided in the switching valve unit 40 is operated and the hydraulic lifting cylinder 10 is moved in the direction of shortening, the vehicle height of the traveling vehicle body 15 begins to decrease. Note that a signal indicating that the elevating operation lever 81 is in the “down” position is output to the control unit 800 by the operation of the elevating operation lever 81.

  Then, when the vehicle body of the traveling vehicle body 15 descends and the sensor plate 710 eventually comes into contact with the farm scene 701, the planting switch 770 is turned on as described in the above item (1), and the signal is transmitted to the control unit. 800 is input.

  Since the planting on / off button 620 remains in the “on” state, the control unit 800 transmits a signal indicating the “on” state from the planting on / off button 620 and a signal indicating the “down” position from the elevating operation lever 81. When the “ON” signal is received from the planting switch 770 under the AND condition, a signal for energizing the solenoid 470 is output. That is, similarly to the above, the control unit 800 outputs a pulse signal at the operation cycle so as to energize the solenoid 470 at a predetermined operation cycle.

  Thereby, the planting clutch 420 is switched from the “cut” state to the “entered” state, and the planting operation is started again.

  With the above configuration, by setting the planting on / off button 620 to the “on” state, the above-described (1) planting operation is started only by operating the elevating operation lever 81, and then (2) the farm field. A series of operations can be carried out continuously, such as traveling while planting inside, and (3) planting again after coming to the end of the fence and turning.

(Embodiment 2)
In the second embodiment, another seedling transplanter according to an embodiment of the transplanter of the present invention will be described with reference to FIGS.

  In the present embodiment, the same components as those in the seedling transplanter 1 of the first embodiment will be denoted by the same reference numerals, and the description thereof will be omitted, and differences will be mainly described.

  That is, in the seedling transplanting machine of the second embodiment, the closing restricting plate 1016 for temporarily restricting the closing operation of the second planting tool 1011 and the swing link mechanism 310 are in the middle of swinging in the vertical direction. The point provided with the projecting member 1311 that temporarily contacts the closing restriction plate 1016 and the point provided with the scraper device 1500 that drops mud and the like adhering to the inner surface and the outer surface of the second planting tool 1011 are described above. It is different from the configuration.

  Further, in the seedling transplanting machine of the second embodiment, the length of the guard is smaller than that of the front guard 1210F and the rear guard 1210B shown in FIG. A second front guard 1220F and a second rear guard 1220B that extend long downward from the lower end of the notch 1200B are provided, and the difference is that the holding of the seedling 22 is stabilized. This point will be further described later.

  In the case of the second embodiment, the rubber spatula member 1511 provided at the tip of the scraper portion 1510 is moved from the front V-shaped notch portion 1200F of the second planting tool 1011 at a predetermined timing. When entering the inside of the two planting tools 1011, the second front guard 1220 </ b> F having elasticity is pushed and bent.

  The spatula-shaped member 1511 of this embodiment corresponds to an example of the scraper of the present invention.

  FIG. 15 is a perspective view of the second seedling planting device 1300 and the second seedling planting device drive mechanism 1400 as viewed from the left rear of the aircraft.

  FIG. 16 is a perspective view of the second seedling planting device 1300 and the second seedling planting device driving mechanism 1400 shown in FIG. 15 as viewed from the right side of the machine body. FIG. 17 is a perspective view of the second seedling planting device 1300 and the second seedling planting device driving mechanism 1400 shown in FIG. 15 as viewed from the left front of the aircraft.

  FIG. 18A is a view for showing the second front guard 1220F and the second rear guard 1220B, and is a plane parallel to the longitudinal direction of the second planting tool 1011 and perpendicular to the ground. It is the schematic sectional drawing which cut | disconnected and saw it from the left side. FIG. 18B is a view for showing the second front guard 1220F. The center part of the second planting tool 1011 is cut by a plane parallel to the left-right direction of the body and perpendicular to the ground. It is the schematic sectional drawing seen from the back side.

  As shown in FIG. 15, the second planting tool 1011 is a pair of left and right left hopper parts 1011L and 1011R, and upper ends of the left hopper part 1011L and the right hopper part 1011R, which temporarily hold seedlings and plant them in the field. The left hopper holder 1012L and the right hopper holder 1012R, and the left hopper holder 1012L and the right hopper holder 1012R, which are detachably connected to each other so as to open and close the front end sides of the left hopper portion 1011L and the right hopper portion 1011R. One end and the other end are fixed to the front lower end of the holder holding frame 1013, the left hopper holder 1012L, and the right hopper holder 1012R which are rotatably held around the fulcrum shaft 1013a, and the left hopper portion 1011L and the right hopper portion 1011R. But The other end of the second open / close connection cable 1350 (reference numeral in FIG. 10) is fixed to the front upper ends of the hopper tension spring 1014 and the left hopper holder 1012L and the right hopper holder 1012R. A pair of left and right open / close arms 1015L and 1015R connected to each other.

  Here, the connecting portion 1012La of the left hopper holder 1012L and the connecting portion 1012Ra of the right hopper holder 1012R have a gear shape, and the gear shape is shifted by half a tooth at the front and rear, and the gears are assembled by facing the left and right sides. It is the structure which meshes | engages.

  As a result, a plurality of line contacts can be made depending on the meshing ratio of the gears, and there is little friction due to rolling contact on the pitch circle.

  In addition, the left hopper holder 1012L and the right hopper holder 1012R can be configured by only a plate material and can be shared between the left and right sides, so that the configuration becomes simple.

  Further, on the front side of the left and right pair of left and right opening / closing arms 1015L, a closing restricting plate 1016 is disposed so as to protrude forward, and is disposed so as to protrude from the rotating upper shaft 317a of the upper arm 311 of the swing link mechanism 310. The protruding member 1311 is fixed at a position where it hits at a predetermined timing.

  Specifically, the protruding member 1311 is configured such that a bolt 1311b is screwed into a tip portion of a plate 1311a protruding from the rotating upper shaft 317a, and a protruding dimension of the bolt 1311b is adjustable. The head of the bolt 1311b hits the closing restriction plate 1016 at a predetermined timing.

  Also, unlike the first embodiment, one end portion 1351 of the second open / close connection cable 1350 of the second embodiment is configured by an elastic spring member. This is because while the bolt 1311b of the protruding member 1311 hits the closing restricting plate 1016 and temporarily blocks the second planting tool 1011 from being completely closed, the size of the blocking amount is absorbed, and the bolt 1311b This is a device for making it possible to completely close the second planting tool 1011 when it is removed from the closing restriction plate 1016.

  In the first embodiment, the open / close arm 340 (see FIG. 10) is rotatably attached via the second connecting shaft 341 on the lower end surface side of the lower arm 312. Then, as shown in FIG. 15, the second opening / closing arm 1340 is rotatably attached to the upper arm surface side of the lower arm 312 via the second connecting shaft 341.

  Next, the configuration of the second front guard 1220F and the second rear guard 1220B will be further described with reference to FIGS. 18 (a) and 18 (b).

  As described above, the second front guard 1220F and the second rear guard 1220B of the present embodiment extend downward downward, and the front end portion 1221F of the second front guard 1220F and the front end portion 1221B of the second rear guard 1220B are It is the structure located just above the root pot 22a of the seedling 22 supplied to the planting tool 1011 (refer Fig.18 (a)).

  Thereby, since the seedling 22 does not float when the planting tool 1011 is lowered, the seedling 22 can be prevented from being exposed inside the planting tool 1011 even if planting is performed at high speed.

  In addition, the left and right corners 1222FL and 1222FR near the front end 1221F of the second front guard 1220F are before the pair of left and right hoppers 1011L and 1011R are completely closed (the stop position of the second planting tool 1011 described later). The pair of left and right hopper portions 1011L and 1011R hits the inner wall surface, and then the pair of left and right hopper portions 1011L and 1011R move in the direction indicated by the arrow M while being pushed by the inner wall surface as they approach each other.

  The same applies to the second rear guard 1220B. The left and right corners 1222BL and 1222BR close to the tip 1221B of the second rear guard 1220B are in front of the pair of left and right hoppers 1011L and 1011R being completely closed (described later, 2 at the stop position of the planting tool 1011), and hits the inner wall surface of the pair of left and right hopper parts 1011L and 1011R, and then, as the pair of left and right hopper parts 1011L and 1011R approach each other, the arrow N indicates It is the structure which moves to a direction.

  With the above configuration, the left and right hopper portions 1011L and 1011R of the second planting tool 1011 are opened at the lower position (for example, the position of the bottom dead center) by the operation of the pair of left and right opening and closing arms 1015L and 1015R and the seedlings 22 After the transplantation, the swing link mechanism 310 draws a predetermined trajectory T1 (see FIG. 1) and gradually closes in the process of moving upward, but the head of the bolt 1311b closes at the top dead center. The seedling 22 released from the extraction member 260 is received at the stop position of the second planting tool 1011 (see timing P3 in FIG. 4) beyond the top dead center in a slightly opened state without being completely closed. . The seedlings 22 released from the take-out member 260 into the second planting tool 1011 are second rear cover 1220F that covers the front V-shaped notch portion 1200F from the inside and second rear cover 1220F that covers the rear V-cut portion 1200B from the inside. By providing the cover 1220B, the second planting tool 1011 is supplied smoothly.

  The second planting tool 1011 receives the seedling 22 and then the head of the bolt 1311b is removed from the closing restriction plate 1016 before entering the soil while descending, so that the restriction of the closing is released and Close completely while moving to rush into the field.

  Thereby, when the planting tool is closed due to the presence of the front V-shaped notch portion 1200F and the rear V-shaped notch portion 1200B described in the first embodiment, the mating surfaces of the left hopper portion 1011L and the right hopper portion 1011R Since the contact portion becomes smaller, noise generated by the contact with the mating surface can be reduced, and the closing operation is temporarily interrupted immediately before the second planting tool 1011 is completely closed. The momentum is reduced and the sound generated when closing is quieter.

  Further, by adjusting the tightening amount of the bolt 1311b to the plate 1311a, the opening amount of the second planting tool 1011 near the top dead center can be adjusted.

  Further, when the second planting tool 1011 receives the seedling 22, the pair of left and right hopper portions 1011L and 1011R are not completely closed and are completely closed after receiving the seedling 22. The seedlings 22 can be firmly clamped, and the posture of the seedling 22 is stabilized inside the second planting tool 1011.

  That is, as the second planting tool 1011 receives the seedling 22, the closing restriction is released while the second planting tool 1011 descends from the stop position, and the pair of left and right hopper portions 1011L and 1011R approach each other as the second front cover 1220F and the second 2 The rear cover 1220B moves in the direction indicated by the arrows M and N while being pushed by the inner wall surface of the second planting tool 1011. Thus, after the second planting tool 1011 receives the seedling 22, the seedling 22 can be more firmly sandwiched by the movement of the second front cover 1220F and the second rear cover 1220B, and the posture of the seedling 22 is stabilized. I can do it.

  The components including the opening / closing cam 322, the hopper tension spring 1014, the pair of left and right opening / closing arms 1015L and 1015R, the second opening / closing arm 1340, the second opening / closing connection cable 1350, and the like according to the present embodiment are the planting of the present invention. This is an example of an accessory opening / closing mechanism.

  Next, with reference to FIGS. 15 to 17, a scraper device 1500 that drops mud adhering to the inner and outer surfaces of the second planting tool 1011, mud adhering to the second front guard 1220 </ b> F and the second rear guard 1220 </ b> B, and the like. explain.

  As shown in FIGS. 15 to 17, the scraper device 1500 includes (1) a scraper unit 1510, (2) a scraper spring 1520, and (3) a scraper cam 1530.

  (1) The scraper unit 1510 is rotatably disposed in front of the second planting tool 1011. Then, the rubber spatula member 1511 provided at the tip of the scraper part 1510 is brought into contact with the inner and outer surfaces of a pair of left and right left hopper parts 1011L and 1011R provided in the second planting tool 1011. In addition, the second front guard 1220F and the second rear guard 1220B are also brought into contact with each other.

  (2) The scraper spring 1520 is a member that biases the spatula-shaped member 1511 toward the pair of left and right hopper parts 1011L and 1011R.

  (3) The scraper cam 1530 is a scraper rotating shaft that is rotated by the rotational driving force supplied from the second seedling planting device drive mechanism 1400 (not shown: in this embodiment, the first cam that drives the open / close cam 322). 1 is a cam member that rotates counterclockwise (see arrow W in FIG. 15) when viewed from the left side, and is pivotally attached to a scraper swing plate 1540 described later. By rotating while contacting the outer peripheral edge of the scraper roller 1541, the scraper swing plate 1540 is swung up and down against the urging force of the scraper spring 1520, and a pair of left and right by the spatula member 1511 The scraper cam 1530 is configured to control the movement toward the left hopper portion 1011L and the right hopper portion 1011R. A large-diameter portion 1530a that protrudes greatly and a small-diameter concave portion 1530b are smoothly connected to each other around a pivot shaft for scraper (not shown: refer to the first connecting shaft 321) that is an axis. In addition, a large-diameter arc-shaped portion 1530a is provided with a medium-diameter portion 1530c in the middle.

  The scraper portion 1510 includes (1) a spatula-like member 1511 and (2) the spatula-like member 1511 disposed at the tip and the other end fixed to a fulcrum 1540a provided through the scraper swing plate 1540. The scraper arm 1512 is provided.

  Note that the shape of the spatula-shaped member 1511 is preferably bent downward so as to surround a virtual axis extending in the horizontal direction of the airframe. This makes it easier for the spatula-shaped member 1511 to slip out and remove mud.

  Further, the shape of the spatula-shaped member 1511 is not limited to the above-described shape, and may be configured to fit the inner walls of the pair of left and right hopper portions 1011L and 1011R, for example, by forming a lump of sponge and forming an inverted truncated cone shape. In this case, the inverted frustoconical portion that is a lump of sponge may be closed so as to be sandwiched between the pair of left and right hopper portions 1011L and 1011R. Thereby, it fits more.

  Further, as shown in FIG. 16, the scraper swinging plate 1540 is rotatably supported on the rear end upper portion of the casing 401 of the second seedling planting device drive mechanism 1400 by a fulcrum portion 1540a. One end 1520 a of the scraper spring 1520 is attached to the front end side of the scraper swing plate 1540, and the other end 1520 b is attached to a spring stay 401 c provided at the upper end portion of the casing 401.

  Thus, the scraper spring 1520 as a tension spring is attached so that the spatula-like member 1511 is always urged toward the pair of left and right left hopper portions 1011L and 1011R.

  In the above configuration, when the scraper cam 1530 is rotated, the range from the small-diameter recessed portion 1530b to the large-diameter portion 1530a of the scraper cam 1530 hits the scraper roller 1541, thereby restoring the scraper spring 1520. The scraper swing plate 1540 is configured to move in a direction in which the scraper arm 1512 is pushed down (clockwise when viewed from the left side) (see arrow S in FIG. 15) against the force (force in the contracting direction).

  In addition, the scraper cam 1530 has a medium diameter portion 1530c that is not in contact with the scraper roller 1541 and floats, and the restoring force (force in the contracting direction) of the scraper spring 1520 is not restricted, and the restoring force is not affected by the scraper. The scraper swing plate 1540 is configured to move in the direction in which the scraper arm 1512 is lifted up (counterclockwise when viewed from the left side) (see arrow T in FIG. 15).

  Next, the operations of the pair of left and right left hopper portions 1011L and 1011R, the scraper cam 1530, and the scraper portion 1510 will be described.

  (1) After the second planting tool 1011 has planted the seedling 22 in the field, the left hopper portion 1011L and the right hopper portion 1011R are raised while being opened.

  At this time, the small-diameter recessed portion 1530b of the scraper cam 1530 is in contact with the scraper roller 1541, and the spatula-shaped member 1511 is opened from the front V-shaped notch portion 1200F of the left hopper portion 1011L and the right hopper portion 1011R. The scraper cam is inserted into the second planting tool 1011 while the second front guard 1220F is bent and the peripheral edge of the spatula-shaped member 1511 is pressed against the inner wall surfaces of the left hopper 1011L and the right hopper 1011R. The scraper portion 1510 moves downward (see the arrow S in FIG. 15) as the position of the 1530 scraper roller 1541 moves from the small diameter recessed portion 1530b to the large diameter portion 1530a.

  During this movement, as shown in FIGS. 15 and 16, the peripheral edge of the spatula-shaped member 1511 scrapes off mud etc. adhering to the inner wall surfaces of the left hopper portion 1011L and the right hopper portion 1011R, and the second front guard 1220F. And the mud etc. adhering to the surface of the second rear guard 1220B is scraped off.

  (2) A state in which the second planting tool 1011 continues to rise and the left hopper portion 1011L and the right hopper portion 1011R are closing.

  At this time, the large-diameter portion 1530a of the scraper cam 1530 is in contact with the scraper roller 1541 and maintains the scraper portion 1510 at the lower position while resisting the force of the scraper spring 1520 in the contracting direction. 1511 comes out of the inside of the left hopper portion 1011L and the right hopper portion 1011R which are being closed.

  (3) A state in which the second planting tool 1011 goes over the top dead center and the left hopper portion 1011L and the right hopper portion 1011R are lowered while being closed.

  At this time, the hollow portion 1511a of the spatula-shaped member 1511 comes into contact with the front side of the outer wall surface of the left hopper portion 1011L and the right hopper portion 1011R, so that the medium diameter portion 1530c of the scraper cam 1530 is lifted from the scraper roller 1541. Accordingly, the scraper spring 1520 is applied with a force in the contracting direction, so that the scraper portion 1510 moves upward (see an arrow T in FIG. 15).

  At this time, the spatula-like member 1511 has already come out of the left hopper portion 1011L and the right hopper portion 1011R, the scraper portion 1510 moves upward, and the left hopper portion 1011L and the right hopper portion 1011R descend. . Therefore, the recess 1511a formed at the tip of the spatula-shaped member 1511 is pressed along the front side of the outer wall surface of the left hopper portion 1011L and the right hopper portion 1011R as shown in FIG. Make sure to scrape off etc.

  (4) The state where the tips of the left hopper portion 1011L and the right hopper portion 1011R of the second planting tool 1011 are completely closed and entered the field.

  At this time, the medium diameter portion 1530c of the scraper cam 1530 is in contact with the scraper roller 1541, and the spatula-shaped member 1511 is in front of the outer peripheral surface on the front side of the left hopper portion 1011L and the right hopper portion 1011R at a position where it does not contact the field. To leave. The outer diameter of the medium-diameter portion 1530c is gradually increased, and hits the scraper roller 1541 when the second planting tool 1011 enters the field.

  Thereafter, the process returns to the item (1) and the above items are repeated.

  According to the scraper device 1500 of the present embodiment, the scraper unit 1510 is forcibly moved by the scraper cam 1530 and the spatula-shaped member 1511 is pulled out from the inside of the left hopper unit 1011L and the right hopper unit 1011R. The left hopper portion 1011L and the right hopper portion 1011R can be scraped within a short range in T1 in FIG.

  Further, according to the scraper device 1500 of the present embodiment, when the spatula-like member 1511 enters the inside of the pair of left and right hopper portions 1011L and 1011R, or when going out from the inside to the outside, the second front guard 1220F and By contacting the second rear guard 1220B, the second front guard 1220F and the second rear guard 1220B can also be scraped.

  Further, the spatula-like member 1511 is pushed out by a scraper spring 1520, and the pair of left and right hopper parts 1011L and 1011R move forward in the ascending process of the second planting tool 1011. Put inside. At that time, the scraper arm 1512 is lowered slightly diagonally from the horizontal, and the spatula-shaped member 1511 is attached to the scraper arm 1512 so as to be substantially perpendicular to the scraper arm 1512. It has become. Therefore, the spatula-shaped member 1511 is likely to enter the pair of left and right hopper portions 1011L and 1011R from below the pair of left and right hopper portions 1011L and 1011R, and within the pair of left and right hopper portions 1011L and 1011R, the hopper portions 1011L and 1011R. By being in contact with the inner wall, it bends and becomes almost horizontal, and the inner wall can be scraped accurately.

  Further, the spatula-shaped member 1511 has a notch (not shown) formed on the side fixed to the scraper arm 1512, and protrudes at a position corresponding to the notch on the scraper arm 1512 side. A portion (not shown) is formed. As a result, when the spatula-shaped member 1511 is attached and fixed to the tip of the scraper arm 1512, the notch is fitted with the protrusion and fixed with a screw or the like, so that even if the screw is loosened, it can be prevented from rotating. Become.

  Further, the spatula-shaped member 1511 has a front portion configured as an attachment portion to the scraper arm 1512, a rear portion configured as a contact portion to the hopper portions 1011L and 1011R, and the attachment portion has a single pin (for example, an attachment bolt). However, even if the contact portion comes into contact with the hopper portions 1011L and 1011R, it is difficult to turn around the pin because the pin faces substantially in the front-rear direction. Further, since the left and right width of the contact portion is wider than the left and right width of the mounting portion, the contact portion is difficult to bend to the left and right and is in a nearly horizontal posture, and can be reliably scraped.

  The second front guard 1220F of the second embodiment is fixed to the front rising portion 1013F of the holder holding frame 1013, and the second rear guard 1220B is the rear end portion and the right frame portion of the left frame portion 1013L of the holder holding frame 1013. Although the structure fixed to the rear end portion of 1013R has been described (see FIG. 18A and FIG. 18B), not limited thereto, for example, as shown in FIG. 19A and FIG. 19B, The third front guard 1230F may be fixed to the left frame portion 1013L of the holder holding frame 1013, and the third rear guard 1230B may be fixed to the right frame portion 1013R of the holder holding frame 1013.

  That is, in the case of this configuration, the third front guard 1230F includes a seedling holding plate portion 1231F extending obliquely downward toward the inner center of the second planting tool 1011 and a front V-shape as shown in FIG. A notch cover plate portion 1232F that substantially covers the notch portion 1200F in rear view (see FIG. 19B), and a fixing portion 1233F for fixing the third front guard 1230F to the left side frame portion 1013L of the holder holding frame 1013 It is composed of The third rear guard 1230B has the same shape as the third front guard 1230F (see FIG. 19C).

  Further, in the case of this configuration, as shown in FIG. 19 (b), one screw hole is provided on each of the distal ends of the pair of left and right hopper portions 1011L and 1011R, and the left plate is interposed through these screw holes. An adjustment bolt 1240L and a right plate adjustment bolt 1240R are rotatably attached. That is, when the left plate adjusting bolt 1240L and the right plate adjusting bolt 1240R are turned, the left bolt front end portion 1241L protrudes from the inner wall surface of the left hopper portion 1011L, and the protruding dimension pushes the seedling holding plate portion 1231F of the third front guard 1230F. At the same time, the right bolt tip portion 1241R protrudes from the inner wall surface of the right hopper portion 1011R to change the protrusion size for pushing the seedling presser plate portion 1231B of the third rear guard 1230B, so that the pair of left and right hopper portions 1011L and 1011R are completely The distance WW (see FIG. 19B) between the seedling presser plate portion 1231F of the third front guard 1230F and the seedling presser plate portion 1231B of the third rear guard 1230B when closed can be adjusted.

  Here, FIG. 19 (a) is a schematic cross-sectional view of the center portion of the second planting tool 1011 cut from a plane parallel to the longitudinal direction of the body and perpendicular to the ground and viewed from the left side, FIG. 19B is a schematic cross-sectional view of the center of the second planting tool 1011 cut from a plane parallel to the left-right direction of the machine body and perpendicular to the ground and viewed from the back side. FIGS. 19A and 19B are views showing the third front guard 1230F and the third rear guard 1230B. FIG. 19C is a perspective view of the third front guard 1230F viewed from the right rear side, and the third rear guard 1230B has the same shape.

  According to this configuration, in addition to being able to cover the front V-shaped notch portion 1200F and the rear V-shaped notch portion 1200B from the inside as in the above configuration example, the size of the seedling 22 and the size of the root pot 22a The interval WW can be appropriately adjusted in advance according to the above. That is, when the second planting tool 1011 receives the seedling 22, the pair of left and right hopper parts 1011L and 1011R are not completely closed, and are completely closed after receiving the seedling 22. The seedling pressing plate portion 1231F of the third front guard 1230F and the seedling pressing plate portion 1231B of the third rear guard 1230B can be firmly sandwiched, and the posture of the seedling 22 is stabilized inside the second planting tool 1011.

  Next, a load adjustment lever 950 for adjusting the load of the pressure reducing wheel 13 will be described with reference to FIG.

  FIG. 20 is a schematic plan view for explaining the load adjustment lever 950. The shape of the operation handle 8a is different from the operation handle 8 (see FIG. 2) of the seedling transplanter 1 described in the above embodiment, but the other configurations are the same.

  The load adjusting lever 950 includes a belt-shaped member 951 formed of a steel strip disposed in the left-right direction of the machine body, a grip portion 952 fixed to one end 951a of the strip-shaped member 951 and protruding rearward, and a grip portion A protruding claw 953 that protrudes rearward from the lower end of the belt-shaped member 951 in the vicinity of 952 is provided.

  The belt-shaped member 951 is disposed substantially horizontally along the left-right direction of the body at a position between the height of the operation handle 8a from the ground and the height of the weight 970, and the other end 951b of the belt-shaped member 951 is It is held on the machine body side so as to be rotatable only in the vertical direction about an axis substantially horizontal to the ground along the longitudinal direction of the machine body. As a result, when the operator grasps the grip portion 952 fixed to one end 951a of the belt-like member 951 and pushes it forward, the belt-like member 951 is directed forward, so that a large number of the upper and lower positions are provided. The protruding claw 953 can be removed from one of the grooves (not shown), and the gripping part 952 is moved forward or downward while being held in the forward direction, and then protruded into any of the groove parts 953. Is inserted again, the height of the central portion 951c of the belt-like member 951 from the ground can be changed.

  As shown in FIG. 20, a weight 970 is disposed at the left and right positions of the rear end portion of the pressure wheel stay 960 with the pressure wheel 13 fixed to the left and right, and the lower end portion of the spring member 980 is connected to the center position. The upper end portion of the spring member 980 is coupled to the central portion 951c of the belt-like member 951 of the load adjustment lever 950.

  Thus, by holding the grip portion 952 of the load adjustment lever 950 and moving the central portion 951c of the belt-like member 951 up and down while releasing the positioning by the protruding claw 953 using the bending of the belt-like member 951, The tension of the spring member 980 can be adjusted, and as a result, the load of the pressure reducing wheel 13 can be adjusted.

  Next, a pressure wheel raising / lowering mechanism 3000 for raising the pressure wheel stay 960 to raise the pressure wheel 13 to a non-working position will be described with reference to FIG.

  FIG. 21 is a schematic side view for explaining a configuration for raising the pressure-reducing wheel 13 to the non-working position, and simultaneously showing the positions of the respective parts from the working state to the non-working state. The state retracted to the non-working position is indicated by a solid line, and the working position and the rising state are indicated by a two-dot chain line.

  As shown in FIG. 21, the pressure reducing wheel stay 960 has a tip portion (not shown) disposed between the left and right rear wheels 3 attached to the rear portion of the traveling vehicle body 15 so as to be rotatable in the vertical direction.

  On the other hand, the pressure-reducing wheel elevating mechanism 3000 includes an elevating wire fixing member 3100, an elevating wire 3110 slidably held by the elevating wire fixing member 3100, and one end connected to one end 3111 of the elevating wire 3110, Elevating and lowering the pressure-reducing wheel, which has a long hole 3210 at the other end and is supported so as to be pivotable in the vertical direction by a horizontal horizontal pivot shaft 3120 provided at the rear end of the lift wire fixing member 3100. Arm 3200, connecting arm 3300 having a pin 3310 protruding in the left-right horizontal direction standing at the center position of rising portion 961 on the rear end side of pressure-reducing wheel stay 960, and pressure-reducing connected to the other end of lifting wire 3110 It is comprised from the wheel raising / lowering operation lever (illustration omitted).

  Further, the lifting wire fixing member 3100 is provided at the left and right central portion of the rear end connecting frame 981 arranged in the left and right direction of the machine body in order to connect the rear end portions of the left and right frames 980 arranged in the left and right pair at the rear portion of the traveling vehicle body 15. It is fixed.

  The pin 3310 fixed to the connecting arm 3300 is slidably inserted into the elongated hole 3210 of the pressure reducing wheel lifting arm 3200.

  In the above configuration, when the pressure wheel 13 is in the working position (see the pressure wheel 13 represented by a two-dot chain line in FIG. 21), the operator operates the pressure wheel lifting / lowering operation lever (not shown), When one end 3111 of the lifting / lowering wire 3110 is pulled in the direction of the arrow WF, the pressure reducing wheel lifting / lowering arm 3200 rotates about the rotation shaft 3120 counterclockwise as viewed from the left side. Since the pressure-reducing wheel lifting arm 3200 is connected to the pressure-reducing wheel stay 960 via a pin 3310 inserted into the elongated hole 3210 of the pressure-reducing wheel lifting arm 3200, the pressure-reducing wheel lifting arm 3200 rotates counterclockwise. The pressure reducing wheel stay 960 is raised while the pin 3310 slides along the inner peripheral edge of the long hole 3210.

  Thereby, the pressure-reducing wheel 13 is raised and held to the non-working position.

  In addition, although the Example of this invention was described in the said embodiment, here, 3rd planting tool 2011 is demonstrated using FIG. 22 as one Example of the invention relevant to this invention.

  FIG. 22 is a view showing the left seedling presser plate 1250L and the right seedling presser plate 1250R. The center part of the third planting tool 2011 is cut by a plane parallel to the left and right direction of the machine body and perpendicular to the ground. It is the schematic sectional drawing which looked at from the back side. The same components as those illustrated in FIGS. 19A to 19C are denoted by the same reference numerals, and description thereof is omitted.

  The shapes of the left seedling presser plate 1250L and the right seedling presser plate 1250R of the third planting tool 2011 are the same as the shapes of the third front guard 1230F shown in FIG. 19C except for the notch cover plate portion 1232F. .

  According to this configuration, the front V-shaped notch 1200F and the rear V-shaped notch 1200B cannot be covered, but the interval WW is appropriately adjusted in advance according to the size of the seedling 22 and the size of the root pot 22a. I can do it. That is, when the third planting tool 2011 receives the seedling 22, the pair of left and right hopper portions 1011L and 1011R are not completely closed, and are completely closed after receiving the seedling 22. The left seedling holding plate 1250L and the right seedling holding plate 1250R can be firmly sandwiched, and the posture of the seedling 22 is stabilized inside the third planting tool 2011.

  Further, in the above embodiment, a case has been described in which the front guard 1210F that covers the front V-shaped notch 1200F from the inside and the rear guard 1210B that covers the rear V-shaped notch 1200B from the inside are provided. For example, the front guard that covers the front V-shaped notch 1200F from the outside and the rear guard that covers the rear V-shaped notch 1200B from the outside may be provided. The V-shaped notch may be covered from the outside and the other V-shaped notched may be covered from the inside. Thereby, the volume in the hopper formed by the pair of left and right hopper portions 1011L and 1011R of the planting tool can be secured.

  In the above-described embodiment, a configuration has been described in which both the front V-shaped notch portion 1200F and the rear V-shaped notch portion 1200B are covered with the front guard and the rear guard. The structure which covers any one of the part 1200F or the back V-shaped notch part 1200B may be sufficient.

  Moreover, although the said embodiment demonstrated the case where the substantially V-shaped notch part was provided in the end surface part mutually opposed of the hopper part divided into right and left, it is not restricted to this, For example, The shape of the notch may be any shape such as a substantially U shape, a substantially long hole shape, a substantially rectangular shape, or a substantially rhombus shape.

  Further, in the above-described embodiment, the notch portion as an example of the present invention is formed on both the right hopper portion and the left hopper portion at the front end surface portion of the hopper portion divided into two on the left and right sides. In addition, in the rear end surface portion of the hopper portion divided into two on the right and left sides, a notch portion as an example of the present invention is formed in both the right hopper portion and the left hopper portion. However, the present invention is not limited to this. For example, in the front end face part of the hopper part divided into two on the left and right sides, the notch part of the present invention is provided on either the right hopper part or the left hopper part. Is formed, and the right and left hopper portions of the right and left hopper portions are arranged at the rear end face portions of the hopper portions that are divided into two on the right and left sides. While the may be an example is formed configuration of the notch of the present invention or Re.

  In the above-described embodiment, the front and rear end surfaces where the left hopper portion 1011L and the right hopper portion 1011R face each other have a substantially V-shaped front V-shaped notch portion 1200F and a substantially V-shaped shape. Although the configuration in which the rear V-shaped notch portion 1200B is provided has been described, the present invention is not limited to this, and for example, a substantially V-shaped notch portion is provided on one of the front and rear end surfaces. It may be a configuration.

  Moreover, in the said embodiment, although the planting tool demonstrated the case provided with the hopper part divided into right and left, it is not restricted to this, For example, the hopper part into which the planting tool was divided into two front and back The structure provided with may be sufficient. In the case of this configuration, an example of the notch portion of the present invention is formed in one or both of the front hopper portion and the rear hopper portion on the left end face portion of the hopper portion that is divided into two in front and rear. An example of the notch of the present invention is provided in one or both of the front hopper part and the rear hopper part in the right end face part of the hopper part which is divided into two parts on the front and rear sides. The board | plate elastic member which is formed and covers this notch part may be provided. Alternatively, in the case of this configuration, an example of the notch portion of the present invention is provided on one or both of the front hopper portion and the rear hopper portion on the left end face portion of the hopper portion that is divided into two in the front-rear direction. Is formed, or in the right end face part of the hopper part divided into two parts in the front and rear, the notch part of the present invention is provided in either or both of the front hopper part and the rear hopper part. An example is formed and the structure provided with the plate-shaped elastic member which covers this notch part may be sufficient.

  Moreover, in the said embodiment, the front-end | tip part 1221F of the 2nd front guard 1220F and the front-end | tip part 1221B of the 2nd rear guard 1220B were supplied to the planting tool 1011 in Fig.18 (a)-FIG.18 (b). Although the structure located immediately above the root pot 22a of the seedling 22 has been described, the present invention is not limited to this, for example, the distal end portion 1221F of the second front guard 1220F and the distal end portion 1221B of the second rear guard 1220B are attached to the planting tool 1011. The length of the supplied seedling 22 reaches the side surface of the root pot 22a (see FIG. 19B), the front side surface of the left hopper portion 1011L (or the right hopper portion 1011R), and the right hopper portion 1011R ( Alternatively, one screw hole is provided on the rear side surface of the left hopper portion 1011L), and the tip of the bolt is inserted through the screw hole provided on the front side surface. The front guard 1220F is pushed rearward, and the tip of the bolt pushes the second rear guard 1220B forward through the front guard adjusting bolt capable of adjusting the pushing dimension and the screw hole provided on the rear side surface, A configuration including a rear guard adjusting bolt capable of adjusting the pushing dimension may be employed. According to this configuration, the distance at the lower end side between the second front guard 1220F and the second rear guard 1220B when the pair of left and right hopper portions 1011L and 1011R are completely closed (see the symbol WW in FIG. 19B). Since it can be adjusted, the interval can be appropriately adjusted in advance according to the size of the seedling 22 and the size of the root pot 22a. Thereby, the received seedling 22 can be firmly sandwiched between the second front guard 1220F and the second rear guard 1220B, and the posture of the seedling 22 is stabilized inside the second planting tool 1011.

  Moreover, in the said embodiment, although the spatula-shaped member 1511 of the scraper apparatus 1500 was demonstrated about the structure made to approach the inside of the 2nd planting tool 1011 from the front V-shaped notch part 1200F of the 2nd planting tool 1011, For example, the second planting tool 1011 may be configured to enter the inside of the second planting tool 1011 through the rear V-shaped notch 1200B.

  Moreover, in the said embodiment, although the taking-out apparatus 200 took out the seedling from the seedling pot 21 of the tray 20, and supplied to the planting tool and planted in the field, it demonstrated, but it was not restricted to this. For example, an operator puts seedlings into a plurality of pots provided on a rotary table by hand, and the seedlings are dropped by opening and closing a lid provided at the bottom of the pot and supplied to a planting tool. The present invention is also applicable to certain types of seedling transplanters.

  Moreover, in the said embodiment, the return operation | movement of the tray feed rod 121 is started after the extraction member 260 rushes into the seedling pot 21, and is completed immediately before the extraction member 260 comes out of the seedling pot 21. However, the present invention is not limited to this. For example, the return operation of the tray feed rod 121 is started and completed in any period from when the take-out member 260 enters the inside of the seedling pot 21 until it comes out. All you have to do is

  Moreover, although the said embodiment demonstrated the structure which performs the planting operation | movement of the planting tool 11 intermittently, it is not restricted to this, For example, the structure which plants a seedling between stocks of a fixed space | interval may be sufficient.

  In the above embodiment, seedlings such as vegetables have been described as transplants. However, the present invention is not limited to vegetables, and any transplants that can be taken out by a take-out device and planted in a field with a planting tool. Also good.

  Further, in the above-described embodiment, the swing link mechanism 310 includes the protruding member 1311 that temporarily contacts the closing restriction plate 1016 in the middle of the vertical swing, and the linkage operation between the closing restricting member 1016 and the protruding member 1311 is performed. However, the present invention is not limited to this. For example, the closing restriction member 1016 and the protruding member 1311 are not provided, and the same opening / closing operation is performed only by the shape of the opening / closing cam 322. It is also possible to adopt a configuration in which

  The seedling transplanter according to the present invention has an effect of suppressing noise without catching seedlings, and is useful as a fully automatic seedling transplanter for taking out seedlings from a pot portion of a tray and planting them in a field.

11 Planting Tool 22 Seedling (Transplant)
310 Swing link mechanism 322 Opening / closing cam (planting tool opening / closing mechanism)
340 Opening and closing arm (planting tool opening and closing mechanism)
350 Connecting cable for opening and closing (planting tool opening and closing mechanism)
400 Seedling planting device drive mechanism 420 Planting clutch 470 Solenoid 1011 Planting tool 1011L Left hopper part 1011R Right hopper part 1014 Hopper tension spring (planting tool opening / closing mechanism)
1015L Opening and closing arm (planting tool opening and closing mechanism)
1015R Opening and closing arm (planting tool opening and closing mechanism)
1200F Front V-shaped notch (notch)
1200B Rear V-shaped notch (notch)
1240L Left plate adjustment bolt (bolt)
1240R Right plate adjustment bolt (bolt)
1500 Scraper unit 1511 Spatula member (scraper)

Claims (4)

The supplied implant (22) is accommodated inside, and the planting tool (11, 1011) whose lower part can be opened and closed in the left-right direction of the machine body and the planting tool (11, 1011) are swung vertically. In the transplanting machine comprising the swing link mechanism (310) to be opened and the planting tool opening / closing mechanism (322, 340, 350, 1014, 1015L, 1015R) for opening and closing the lower part of the planting tool (11, 1011),
In the planting tool (11, 1011), a notch (1200F, 1200B) is formed on one or both of the front and back of the end face portions of the two divided portions that are abutted with each other. A plate-like elastic member that covers the notch (1200F, 1200B) when the portion is closed is provided inside the planting tool (11, 1011);
The transplanter (22) accommodated in the planting tool (11, 1011) is held via the plate-like elastic member. The planting tool (11, 1011) includes a left hopper part (1011L) and a right hopper part (1011R), and the notch part (1200F, 1200B) includes the left hopper part (1011L) and the right hopper part. (1011R) is formed on each of the front and rear end portions that are abutted against each other,
The transplanter according to claim 1, wherein the plate-like elastic member is provided on each of a front side and a rear side of the planting tool (11, 1011).   Screw holes are respectively formed in the left hopper portion (1011L) and the right hopper portion (1011R), and bolts (1240L, 1240R) are inserted into the screw holes so as to be able to advance and retreat, and the tips of the bolts (1240L, 1240R) are inserted into the plate. The transplanter according to claim 2, wherein the transplanter is configured to contact the back side of the elastic member. A scraper device (1500) for bringing the scraper (1511) into contact with the inner surface of the planting tool (11, 1011);
When the scraper (1511) is inserted into the planting tool (11, 1011), the scraper (1511) enters the planting tool (11, 1011) while pushing away the elastic plate member. The transplanter according to any one of claims 1 to 3.

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