JP2015208292A - Seedling transplanter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a seedling transplanter including a simple constitution of a transmission system, facilitating supply of a lubricant, and capable of reliably leveling a field surface without damaging a land leveling device.SOLUTION: The seedling transplanter includes: a seedling loading member 51 installed on a vehicle body 2, loading seedlings for a field, and being freely lifted/lowered; and a support member 403 under the seedling loading member 51. The seedling transplanter also includes on the support member 403: a land-leveling device 5 leveling a field surface; a drive case 406 receiving a drive force from the vehicle body 2; and plural planting transmission cases 405C, 405L, 405R supplying the drive force to a seedling planting device 408 planting seedlings, a planting transmission shaft 407 arranged in the drive case 406 supplying the drive force to the plural planting transmission cases 405C, 405L, 405R.

Description

  The present invention relates to a seedling transplanter including a seedling planting unit for planting seedlings in a field and a leveling device for leveling a field scene.

  In a seedling transplanter equipped with a seedling planting part at the rear part of the machine body for planting seedlings in the field, a planting transmission shaft that rotates by receiving driving force from the engine and transmission case of the traveling vehicle body is provided, and each planting from this planting transmission shaft There exists a configuration for supplying a driving force to the transmission case.

  In the seedling transplanting machine described in Patent Document 1, the same number of input bevel gear mechanisms as the planting transmission cases are provided on the planting transmission shaft provided in the left-right direction of the machine body, and the drive rotation shaft rotated by the bevel gear mechanism is provided. , Each planted on the planting shaft. The left and right seedling planting devices are driven to rotate by receiving a driving force from the output-side bevel gear mechanism provided at the rear end of the planting transmission shaft.

In addition, there is a seedling transplanter configured to include a leveling device for leveling the unevenness of the field scene where the seedling planting device plants a seedling, below the seedling planting unit.
The seedling transplanting machines described in Patent Literature 2 and Patent Literature 3 are provided with a leveling device including a center rotor and a pair of left and right side rotors. By leveling, the seedling planting depth by the seedling planting device is made constant.

JP 2001-314109 A JP 2012-179014 A JP 2009-232715 A

  However, in the seedling transplanter of Patent Document 1, since the drive rotation shaft is rotated from the planting transmission shaft via the bevel gear mechanism, a driving loss is likely to occur, and the planting timing of the seedling planting device is disturbed. There is a problem that the planting accuracy decreases.

Further, since the bevel gear mechanism requires a pair of bevel gears, the number of parts increases, and there is a problem that the weight of the machine body and the man-hour for assembly work increase.
Furthermore, it is necessary to supply the lubricant (oil) for smoothly rotating the bevel gear mechanism and preventing seizure to both the input side and the output side bevel gear mechanism. In addition, there is a problem that the amount of lubricant used increases.

  Further, in the seedling transplanter of Patent Document 2, the side rotor is supported by the rotor suspension frame suspended from the seedling planting part, and the center rotor is supported from the side rotor via the rotor transmission case. In the situation where the rotors of the leveling device are weakly connected to each other and the rotors are deeply embedded in the field, there is a problem that they are easily damaged.

  In particular, when the center rotor is connected to a suspension spring provided in the seedling planting part, when the seedling planting part is raised, the center rotor may hang down and come into contact with the surface of the field. If the center rotor is in contact with the surface of the field during turning, the dragged center rotor will roughen the surface of the field, causing large irregularities when planting seedlings in the corners of the field, i.e. headlands, There is a problem that the depth becomes too shallow or too deep.

  Furthermore, in the seedling transplanter of Patent Document 3, if the vertical sliding mechanism cannot be smoothly slid due to long-term use, the leveling device will not move up and down as set, and the leveling device will sink into the field and There is a problem that the planting depth of the seedling becomes unstable due to roughening.

  And by suspending the leveling device from both the left and right sides, the weight of the leveling device concentrates in the center of the horizontal direction of the leveling device, and the leveling device deforms due to accumulation of load for a long time, and the leveling ability is reduced. There is a problem that decreases.

  An object of the present invention is to provide a seedling transplanting machine that has a simple configuration such as a transmission system, can easily supply a lubricant, and can evenly level a field scene without damaging the leveling device. And

The above-mentioned problem of the present invention is solved by the following means.
The present invention according to claim 1 is provided such that a seedling placing member (51) for loading seedlings on a field is provided on the traveling vehicle body (2) so as to be movable up and down, and a support member (403) is provided below the seedling placing member (51). , A leveling device (5) for leveling the farm scene on the support member (403), a driving case (406) for receiving driving force from the traveling vehicle body (2), and a plurality of seedling planting devices (408) for planting seedlings A plurality of planting transmission cases (405C, 405L, 405R) for supplying a driving force to the driving case (406) are provided, and the plurality of planting transmission cases (405C, 405L, 405R) is configured to supply driving force to a seedling transplanter.

  According to a second aspect of the present invention, a lubricant is enclosed in the plurality of planting transmission cases (405C, 405L, 405R), and a planting transmission member is disposed in the plurality of planting transmission cases (405C, 405L, 405R). A planting drive rotating body (410) that rotates with the driving rotation of (407), and a planted driven rotating body (411) that rotates from the planting drive rotating body (410) via a planting transmission endless belt (412). And a planting rotation shaft (409) for rotating a plurality of seedling planting devices (408) on the planting driven rotating body (411), respectively, and the planting rotation shaft (409) is set as a planting transmission shaft (407). The seedling transplanter according to claim 1, wherein the seedling transplanter is disposed at a lower position than the above.

  According to the third aspect of the present invention, in the plurality of planting transmission cases (405C, 405L, 405R), the planting drive rotating body (410) has a vertical width on the side where the planted driven rotating body (411) is provided. The width of the planted driven rotating body (411) is larger than the diameter of the planting drive rotating body (410). A seedling transplanter.

  According to the present invention, the left and right moving device (404) for moving the seedling placing member (51) in the lateral direction of the machine body is mounted on the drive case (406), and the traveling case is placed in the drive case (406). A transmission mechanism (406a, 406b, 406c, 406d) for transmitting the driving force received from the vehicle body (2) to the left and right moving device (404) and the planting transmission shaft (407) is provided, and the driving case (406) is disposed on the left side case. (406L) and a right case (406R), wherein either the left case (406L) or the right case (406R) is detachably provided from the other. A seedling transplanter according to item 1 was used.

  According to a fifth aspect of the present invention, there is provided a clutch mechanism that interrupts transmission of driving force when the planting transmission shaft (407) is overloaded to the plurality of planting transmission cases (405C, 405L, 405R). (416) was provided, It was set as the seedling transplanter of any one of Claim 1 to 4 characterized by the above-mentioned.

  According to the sixth aspect of the present invention, the leveling device (5) includes a side leveling member (51, 51) provided at both right and left ends of the traveling vehicle body (2), and the side leveling member (51, 51). A center leveling member (50) provided between the left and right sides of the machine body, and a leveling transmission case (52, 52) for connecting the center leveling member (50) and the side leveling members (51, 51) and transmitting a driving force. ), And a leveling device (62) for raising and lowering the leveling device (5) at the seedling planting part (4), and a posture of the traveling vehicle body (2) of the leveling device (5) in the front-rear direction. The seedling transplanting machine according to any one of claims 1 to 5, wherein a horizontal maintaining mechanism (63) for maintaining the level is provided.

  In the seventh aspect of the present invention, the leveling lift device (62) includes a lift drive actuator (65) in the seedling planting part (4) and a lift transmission member (64) rotated by the lift drive actuator (65). ) And a leveling / lowering member (66) that moves up and down by the rotation of the lifting / lowering transmission member (64), and the horizontal maintaining mechanism (63) is provided with a horizontal maintaining member (69 provided on the front side of the leveling / lowering member (66)) And a posture holding member (71) that protrudes rearward from the leveling transmission case (52) and contacts the horizontal maintenance member (63). .

  The present invention according to claim 8 is provided with an anti-scattering member (85) for preventing mud from scattering above the central leveling member (50), the anti-scattering member (85) being the central leveling member (50). The support body (86, 86) provided on the left and right sides of the support body and the protective body (87) for connecting the front side of the support body (86, 86), and the upper and rear sides of the central leveling member (50) are opened. A seedling transplanter according to claim 6 or 7, wherein:

  According to the present invention, the driving force is supplied to the plurality of planting transmission cases (405C, 405L, 405R) by the planting transmission shaft (407) that receives the driving force from the driving case (406). It is not necessary to provide a relay transmission member between the planting transmission shaft (407) and the planting transmission case (405C, 405L, 405R), reducing the transmission loss of the driving force and reducing the number of parts. Figured.

Moreover, since the space which provides the transmission member for relay becomes unnecessary, it can prevent that the front-back width | variety of a seedling planting part (4) becomes long.
According to the second aspect of the present invention, in addition to the effect of the first aspect of the invention, the planting rotation shaft (409) is disposed below the planting transmission shaft (407), so that the planting follower is provided. Since the planting transmission endless band (412) protrudes downward on the rotating body (411) side, the enclosed lubricant can be carried by the planting transmission endless band (412), wear of the member is reduced, and durability is improved. Will improve.

Further, since the driving loss of the planting transmission endless belt (412) can be reduced, the planting position of the seedling planting device (409) is prevented from being disturbed, and the seedling planting accuracy is improved.
According to the third aspect of the present invention, in addition to the effect of the invention according to the second aspect, in the planting transmission case (405C, 405L, 405R), on the side where the planted driven rotating body (411) is provided. By forming the vertical width wider than the vertical width on the side where the planting drive rotor (410) is provided, the enclosed lubricant is likely to accumulate at the bottom of a wide part, so even a small amount of lubricant can be planted. It is easy to contact the transmission endless belt (412), and the amount of lubricant used can be reduced.

  Furthermore, since the diameter of the planting driven rotating body (411) is larger than the diameter of the planting driving rotating body (410), the planting transmission endless band (412) protrudes downward, so that the enclosed lubrication is performed. The agent can be carried by the planting transmission endless belt (412), wear of the member is reduced, and durability is improved.

And since the drive loss of a planting transmission endless belt (412) can be reduced, it is prevented that the planting position of a seedling planting device (409) is disturbed, and the seedling planting accuracy improves.
Further, since the amount of lubricant to be sealed can be reduced, the lubricant is less likely to leak out from the planting transmission case (405C, 405L, 405R), and contamination of water and soil in the field and surroundings is prevented.

  According to this invention of Claim 4, in addition to the effect of the invention of any one of Claims 1 to 3, the left case (406L) of the drive case (406) provided on the support member (403) Alternatively, either one of the right case (406R) is detachably provided from the other, so that the transmission mechanism (406a, 406b, 406c, 406d) is exposed when the left case (406L) or the right case (406R) is removed. Therefore, maintenance work and parts replacement work of the transmission mechanism (406a, 406b, 406c, 406d) can be easily performed, and work efficiency and maintainability are improved.

  According to this invention of Claim 5, in addition to the effect of the invention of any one of Claims 1 to 4, by providing a clutch mechanism (416) on the planting transmission shaft (407), Since supply of driving force can be interrupted when an overload is applied to a plurality of planting transmission cases (405C, 405L, 405R), damage to the seedling planting unit (4) is prevented.

  According to this invention of Claim 6, in addition to the effect of the invention of any one of Claim 1 to 5, the horizontal maintenance mechanism (63) which hold | maintains a leveling apparatus (5) with a horizontal attitude | position is provided. As a result, it is possible to prevent the leveling device (5) from sinking into the field due to its own weight or the like during the work, so that the leveling device (5) prevents the surface of the field from being roughened, and leveling accuracy and planting of seedlings are prevented. Attachment accuracy is improved.

  Moreover, since the leveling work height of the leveling device (5) can be easily adjusted by providing the leveling lifting device (62), the unevenness on the surface of the field is surely leveled, and the seedling planting depth Can be kept constant.

  According to the seventh aspect of the present invention, in addition to the effect of the sixth aspect of the present invention, the leveling work height of the leveling device (5) can be increased by moving the leveling lifting member (66) up and down by the leveling lift actuator (65). By changing the height, the leveling work height can be set finely, so that the leveling accuracy is further improved.

  In addition, the rear end portion of the posture maintaining member (71) of the horizontal maintenance mechanism (63) is in contact with the horizontal maintenance member (69), so that the leveling device (5) is more than horizontal with respect to the surface of the field. Since it can control that the central leveling member (50) is rotated downward, the central leveling member (50) can be prevented from roughing the surface of the field, improving the seedling planting accuracy and planting depth. Stableness is achieved.

  According to the present invention described in claim 8, in addition to the effects of the invention described in claim 6 or 7, the anti-scattering member (85) connects the front sides of the left and right supports (86, 86) ( 87), it is possible to prevent the mud from scattering to the front side of the machine body due to the rotation of the central leveling member (50), so that the mud may be scattered to the operator who is boarding the traveling vehicle body (2). Is prevented.

  Moreover, since the scattering prevention member (85) has opened the upper direction and the back of the central leveling member (50), it can prevent clogging of mud between the central leveling member (50) and the scattering prevention member (85). And the fall of work efficiency is prevented and the leveling accuracy improves, without driving the leveling device (5).

Side view of a seedling transplanter with a stacking configuration for the spare seedling placement part Side view of a seedling transplanter with the preliminary seedling placement section deployed Top view of the seedling transplanter with the preliminary seedling placement part as a stacked form Top view of the seedling transplanter with the preliminary seedling placement part deployed Front view of a seedling transplanter with a stacking configuration for the spare seedling placement part Side view of the spare seedling placement part in a stacked form, seen from the outside of the seedling transplanter Side view of the spare seedling placement part in a stacked form, as seen from the operation part side of the seedling transplanter Side view of the spare seedling placement part in the expanded form, seen from the outside of the seedling transplanter Side view of the spare seedling placement part in the deployed form, as seen from the operating part side of the seedling transplanter Side view of the preliminary seedling placement part in a stacked form, provided with a stop member Side view of the main part of the preliminary seedling placement part in a stacked form showing the arrangement of the stop member Side view of the preliminary seedling placement part in a deployed form, provided with a stop member Side view of the main part of the preliminary seedling placement part in the expanded form showing the arrangement of the stop member (A) Side view of the main part of the preliminary seedling placement unit provided with a front protrusion and a conveyance auxiliary rotating body showing movement of the loaded seedling, (b) Front projection and conveyance assistance showing movement of the loaded seedling Side view of the main part of the preliminary seedling placement unit provided with the rotating body, (c) Plan view of the main part of the preliminary seedling placement part provided with the front side protruding part and the conveyance auxiliary rotating body, (d) Front side protruding part and conveyance auxiliary Enlarged side view of a spare seedling mounting member provided with a rotating body Plan view of the pre-seedling placement part in the unfolded form Operation control block diagram of spare seedling placement unit Explanatory drawing showing the structure of the switching unit (A) The principal part side view of the switching device of a preliminary seedling mounting part, (b) The principal part top view of the switching device of a preliminary seedling mounting part Main part plan view showing movement trajectory of fertilizer mounting table Front view of main part of seedling transplanter with fertilizer mounting table Main part plan view showing planting transmission system of seedling planting part Rear view of the main part showing the frame structure of the seedling planting part Side view of the main part of the seedling planting part Principal tribe of planting transmission case Side view of main part of planting drive case Main part enlarged plan view showing planting transmission system of seedling planting part Main part plan view showing the leveling device Principal part plan view showing the planting transmission system of the seedling planting part of another configuration Side view of main part showing vertical movement mechanism of seedling planting part, leveling device and leveling device Plan view of main parts of leveling device Side view of the main part when the leveling device is at the lowest position The principal part side view of the state which the leveling apparatus shown by FIG. 31 raised The principal part side view of the state which has the leveling apparatus shown in FIG. 31 in the highest position Side view of the main part, showing a partial section of the retraction mechanism of the leveling device Side view of main part showing scattering prevention member of leveling device Plan view of the main part showing the oil supply route of the traveling vehicle body Side view of the main part showing the inter-plant switching mechanism of the seedling planting device Plan view of the main part showing the inter-plant switching mechanism of the seedling planting device

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows a side view of a seedling transplanter according to Embodiment 1 of the present invention when the preliminary seedling placement portion is in a laminated form, that is, in a laminated form in which preliminary seedling placing members are arranged in the vertical direction, and FIG. The side view of the seedling transplanting machine when the preliminary seedling placement portion is in the deployed form, that is, in the deployed form in which the spare seedling placing members are arranged in the front-rear direction, is shown. FIG. 3 is a plan view of the seedling transplanting machine when the preliminary seedling placement unit is in a stacked form according to the first embodiment, and FIG. 4 is a seedling transplantation when the preliminary seedling placement unit is in a deployed form. A plan view of the machine is shown. FIG. 5 is a partial front view of the seedling transplanter of the first embodiment, and shows a state in which the preliminary seedling placement unit is in a stacked form.

The following embodiment is merely an embodiment and does not restrict the scope of patent registration.
In the present specification, the front / rear and left / right direction reference defines the front / rear and left / right reference based on the traveling direction of the vehicle body as viewed from the driver's seat.

  As shown in FIGS. 1 to 5, a driver's seat 12 is provided at the rear of the floor step 11 in the driver 10 of the traveling vehicle body 2. A bonnet 13 that covers the engine 210 is provided in front of the floor step 11, and a steering handle 18 that steers the front wheels 14 is provided above the bonnet 13. Right and left auxiliary steps 27 are provided on the left and right outer sides of the floor step 11. In the following, the explanation will focus on the left side of the vehicle body. 1 and 2, 4 is a seedling planting portion provided on the rear side of the vehicle body, 16 is a lifting link mechanism for raising and lowering the seedling planting portion 4, 15 is a rear wheel, and 17 is a fertilizer.

  As shown in the figure, a fuel tank 300 is provided at the center in the left-right direction on the front side of the traveling vehicle body 2, and an engine 301 is provided at the center in the front-rear direction and the left-right direction. Then, the outer periphery of the engine 301 is covered with an engine cover 302, and the driver seat 12 is provided on the engine cover 302.

  The fuel tank 300 and the engine 301 are connected by a fuel pipe 303 for supplying fuel. The fuel pipe 303 is bent to the right side of the body at the rear of the fuel tank 300 and is located on the inner side of the body from the rear wheel 15. And bent so as to be reversed to the front side of the body at the side of the engine 301 and bent so as to be reversed to the rear side of the body at the front side of the engine cover 302.

  A radiator 304 that cools the engine 301 is provided on the right side of the body of the engine 301, and the periphery of the radiator 304 is covered with a radiator cover 305. Of the radiator cover 305, a fuel filter 307 for restricting the passage of fine particles mixed in the fuel is provided on the right side of the body facing the fuel pipe 303 from the front side to the rear side of the radiator cover 305, inside the radiator cover 305, and A fuel pump 306 that feeds fuel from the fuel tank 300 to the engine 301 is provided at a position where the fuel pipe 303 is directed from the rear side to the front side of the machine body, and a discharge cock 308 that discharges fuel to the outside at the front portion outside the radiator cover 305. Is provided. Further, a muffler 309 for exhausting exhaust generated by the operation of the engine 301 is arranged on the left side of the body of the engine 301 toward the rear side of the body.

  With the above configuration, the radiator cover 305 can be used as an attachment support member for the fuel pump 306, the fuel filter 307, and the discharge cock 308, so that no other attachment members are required, and the number of parts can be reduced.

  Further, since the fuel pump 306, the fuel filter 307, and the discharge cock 308 can be centrally arranged on the right side of the machine body, maintenance work can be performed only on the right side of the machine body, so that maintainability is improved.

  By providing the fuel pump 306 inside the radiator cover 305, the radiator cover 305 serves as a mudguard cover of the fuel pump 306, so that water and mud are less likely to adhere to the fuel pump 306 and damage is prevented.

  Furthermore, since the fuel filter 307 is provided on the right side of the body of the radiator cover 305, the fuel filter 307 can be easily reached, so that the fuel filter 307 can be easily replaced.

  Since the muffler 309 is provided on the left side of the fuselage, high-temperature exhaust heat hardly affects the fuel pipe 303 or the radiator 304 side. Is stable.

  As shown in FIGS. 21 to 2, a seedling tank 401 in which a seedling mounting portion on which a plurality of seedlings are loaded is supported by a planting support frame 402, and unevenness of a farm scene is leveled below the planting support frame 402. A leveling support frame 403 for supporting the leveling device 5 is provided, and a driving force is obtained from the traveling vehicle body 2 at the upper part of the leveling support frame 403 and at a substantially central position in the left-right direction of the aircraft, and a later-described lead cam mechanism 404 and a plurality of planting devices are provided. A planting drive case 406 for supplying a driving force to the auxiliary transmission cases 405C, 405L, and 405R is provided.

  In addition, the leveling support frame 403 can be formed with a hollow inside and provided with a plurality of partitions, whereby the strength can be improved with almost no loss of light weight. The plurality of planting transmission cases 405C, 405L, and 405R can be secured by attaching them to the leveling support frame 403 via fixing members (not shown) such as bolts.

  A lead cam mechanism 404 for sliding the seedling tank 401 in the left-right direction is provided above the leveling support frame 403, and the lead cam shaft 404a of the lead cam mechanism 404 is connected to the lateral feed gear unit 406b in the planting drive case 406. Installing. The lateral feed gear unit 406b can change the combination of gears, and can switch the left-right reciprocating sliding speed of the seedling tank 401.

  Further, the planting drive case 406 is configured by connecting a left case 406L and a right case 406R, and the left case 406L is detachably attached to the leveling support frame 403 with a fixing member such as a bolt. Further, the right case 406R is detachably attached to the left case 406L with a fixing member such as a bolt. Note that, as shown in FIG. 21, the left case 406L is in contact with the right side of the center planting transmission case 405C.

A rolling rotation shaft 417 is mounted on the front side of the left case 406L as a fulcrum when the seedling planting portion 4 rotates in the left-right direction.
Also, a plurality of planting transmission cases 405C, 405L, 405R are provided at the rear of the leveling support frame 403, and the plurality of planting transmission cases 405C, 405L, 405R are connected by a planting transmission shaft 407 that is long in the left-right direction of the machine body. To do. Further, the planting transmission shaft 407 is mounted with a planting output gear 406d for transmitting a driving force from the lateral feed gear unit 406b via the counter gear 406c.

  Further, the planting drive case 406 is provided with a bevel gear mechanism 406a that receives driving force from the PTO shaft 2p of the traveling vehicle body 2 and supplies the driving force to the lateral feed gear unit 406b on the front side of the machine body.

  Since the planting drive case 406 is provided at a substantially central position in the left-right direction of the machine body, the planting output gear 406d is located near the center planting transmission case 405c provided near the center in the left-right direction, or It arrange | positions in the position adjacent to the center planting transmission case 405c.

  The plurality of planting transmission cases 405C, 405L, and 405R are provided with a planting rotation shaft 409 that outputs a driving force in the left-right direction, and seedling planting for planting seedlings on the left and right sides of the planting rotation shaft 409 in the field. An attachment device 408 is provided. Note that a plurality of unequal circular gears are provided inside the seedling planting device 408 so that the seedling planting posture by the seedling planting device 408 is substantially perpendicular to the field scene, and the planting rotation shaft 409 is provided. In order to improve the efficiency of planting work, two or more seedling picking claws are mounted.

The said seedling planting part 4 is comprised by the above.
Then, as shown in FIG. 21, a planting drive sprocket 410 to be mounted on the planting transmission shaft 407 is disposed on the front side of the machine body inside the right and left side and center planting transmission cases 405C, 405L, 405R. On the rear side, a planted driven sprocket 411 mounted on the planting rotation shaft 409 is disposed. Further, the planting transmission chain 412 is wound endlessly across the planting drive sprocket 410 and the planting driven sprocket 411, and the rotational driving force of the planting transmission shaft 407 is transmitted to the planting rotary shaft 409. To do.

  The planting rotary shaft 409 is splined on the outer peripheral edge, the bearing hole of the planted driven sprocket 411 is shaped to correspond to the spline processing of the planting rotary shaft 409, and the planting rotary shaft 409 and the planted driven sprocket It is configured to prevent the rotation of 411 from not matching. At this time, if the number of teeth formed on the outer peripheral edge of the planted driven sprocket 411 is the same as the number of convex portions by spline processing, the planted driven sprocket 411 can be easily attached and detached, and phase alignment during assembly can be achieved. Since it can be easily performed, the work efficiency and maintenance can be improved.

  The plurality of planting transmission cases 405C, 405L, and 405R are configured such that the vertical length becomes longer toward the rear side of the machine body, and the planting rotation shaft 409 is disposed below the machined transmission shaft 407. A configuration that can be arranged. In addition, even if the planted driven sprocket 411 has a larger diameter than the planting drive sprocket 410, the planted driven sprocket 411 can be stored in the rear side of the plurality of planting transmission cases 405C, 405L, and 405R.

  A chain tensioner 413 that receives the planting transmission chain 412 from below is provided to prevent the planting transmission chain 412 from drooping downward, and the seedling planting device 408 has a backlash caused by non-uniform rotation (backlash). ), When the rotation of the planted driven sprocket 411 is disturbed, the planted transmission chain 412 is prevented from causing a chain jump or the like.

  The chain tensioner 413 is formed by bending a resilient material that is strong and elastic, such as spring steel. The front and rear ends and the substantially central portion in the front-rear direction are in contact with the inner lower portions of the plurality of planting transmission cases 405C, 405L, and 405R. At the same time, two contact protrusions 413a that contact the planting transmission chain 412 are formed.

  Then, a push bolt 414 that contacts the chain tensioner 413 is rotatably inserted into an outer lower portion of the plurality of planting transmission cases 405C, 405L, and 405R, and the chain tensioner 413 is inserted into and removed from the chain tensioner 413. The force for energizing 412 is adjusted.

Further, an oil filling port 415 is provided in the rear part of the plurality of planting transmission cases 405C, 405L, 405R, and the oil filling port 415 is opened so that oil can be injected.
Further, on the side of each planting drive sprocket 410, a breakage prevention clutch mechanism 416 is provided to prevent the planting transmission chain 412 and the planting rotary shaft 408 from being overloaded when an overload occurs. ... are provided. The plurality of breakage prevention clutch mechanisms 416 are energized so that the clutch pawl 416a and the clutch pawl 416a are engaged with each other, and when overloaded, the clutch pawl 416a contracts to separate the clutch pawl 416a. The clutch spring 416b is set to the “OFF” state.

  In the above configuration, the planting transmission shaft 407 is provided directly on the plurality of planting transmission cases 405C, 405L, and 405R to transmit the driving force, so that between the planting transmission shaft 407 and each planting drive sprocket 410. In addition, parts that transmit the driving force are not required, and weight and cost can be reduced by reducing the number of parts.

  Further, the left side case 406L is provided on the leveling support frame 403, and the right side case 406R is detachably provided on the leveling support frame 403, so that when the right side case 406R is removed, maintenance work and component replacement inside the planting drive case 406 are performed. Can be done easily and work efficiency is improved.

  Since the plurality of planting transmission cases 405C, 405L, and 405R are configured to be longer in the vertical direction toward the rear side of the machine body, the lubricating oil such as oil introduced from the oil filling port 415 is accumulated on the rear side of the machine body. When the planting transmission chain 412 having a large diameter moves, the accumulated lubricant can be carried, and the movement of the planting transmission chain 412 is stabilized.

  As a result, it is not necessary to fill the interior of the plurality of planting transmission cases 405C, 405L, and 405R, so that the amount of lubricant used is reduced and the lubricant leaks into the field, causing water and soil to leak. Contamination is prevented.

  Furthermore, parts in the plurality of planting transmission cases 405C, 405L, and 405R are prevented from moving due to seizure or the like, and work is prevented from being interrupted or a missing section where seedlings are not planted is prevented. The

  Further, by pressing the planting transmission chain 412 upward with the chain tensioner 413, it is possible to prevent the planting transmission chain 412 from slipping and the rotational speed of the planting rotation shaft 409 from being increased or decreased. The planting interval is easily aligned, and the planting rotation shaft 409 is stopped, thereby preventing the occurrence of a missing plant section in which seedlings are not planted.

  Then, by rotating the push bolt 414 in and out, the urging force of the chain tensioner 413 to the planting transmission chain 412 can be changed, so that the planting transmission chain 412 is loosened by the rotation of the seedling planting device 408. It is possible to prevent dripping or turning too quickly, and the need for manually planting seedlings in the missing section is eliminated.

  Further, by providing a plurality of breakage prevention clutch mechanisms 416... On the side of the planting drive sprocket 410, the planting drive sprocket 410 is turned off when overloaded, and the planting driving force to the corresponding strip is temporarily interrupted. Therefore, the members in the planting transmission cases 405C, 405L, and 405R and the seedling planting device 408 can be prevented from being damaged by the load, and the planting accuracy of the seedling can be maintained.

  The seedling planting part 4 is a six-planted seedling transplanter as shown in FIG. 21, but the seven-planted rice transplanter shown in FIG. It is necessary to replace the center planting transmission case 405CL, 405CR. In addition, the right center planting transmission case 405CR has a planting rotation shaft protruding only on either the left or right side and only one seedling planting device 408 is mounted in order to realize odd-numbered planting. .

  At this time, the right center planting transmission case 405CR is arranged to be spaced apart from the planting drive case 406 in the left-right direction. The right central transmission case 405CR provided with one seedling planting device 408 is lighter than the other transmission cases 405CL, 405L, 405R that rotationally drive the two seedling planting devices 408, 408. Therefore, such a configuration is adopted.

  As a result, the right and left balance of the seedling planting part 4 is stabilized, so that the seedling planting part 4 is prevented from rolling due to weight deviation, and the seedling planting depth in all the strips is constant, Growth is stable.

The planting support frame 402 is configured as follows.
As shown in FIG. 22, left and right vertical frames 418 and 418 are provided on the left and right upper portions of the leveling support frame 403, respectively, and upper ends of the left and right vertical frames 418 and 418 are connected by an upper frame 419 that is long in the horizontal direction of the body. . A lower frame 420 that connects the left and right vertical frames 418 and 418 is provided at a height position below the upper frame 419 and above the center of the left and right vertical frames 418 and 418 in the vertical direction.

  Further, an intermediate frame 421 is provided between the upper and lower sides of the lower frame 420 and the leveling support frame 403 and at a position closer to the left side than the central portion in the left-right direction of the machine body. Further, a motor stay 422 for providing a rolling motor 423 is provided at the center position in the left-right direction of the lower frame 420. The motor stay 422 and the left and right vertical frames 418 and 418 are connected by balance springs 424 and 424, respectively. The left and right balance springs 424 and 424 urge the motor stay 422 outward from the left and right sides of the machine body, and when the seedling planting portion 4 is rotated by the rolling rotation shaft 417 in addition to the operation of the rolling motor 423, The posture is automatically returned.

In addition, even if the number of planting strips increases or decreases, the above configuration does not change.
Further, mounting stays 425 and 425 are provided on the left and right sides of the leveling support frame 403, and stand guards 426 and 426 are provided on the left and right mounting stays 425 and 425, respectively, with the pivoting fulcrum in the longitudinal direction of the body as the center. From the position that protrudes to the left and right, it is mounted so that it can be rotated 90 degrees toward the bottom of the aircraft.

  When the left and right stand guards 426 and 426 are protruded to the left and right sides of the machine body, the stand guard 426 adjacent to the farm field end comes into contact with the end of the farm field first, especially when working at the farm field edge. Therefore, the constituent members of the seedling planting unit 4 are prevented from coming into contact with the field edge, and the seedling planting unit 4 is prevented from being damaged.

  When the left and right stand guards 426 and 426 are rotated downward, the left and right stand guards 426 and 426 first come into contact with the ground when the seedling planting part 4 is lowered. If 426 and 426 are rotated downward, it is possible to prevent the seedling planting part 4 from being damaged due to excessive lowering operation.

The leveling support frame 403 may be detachably provided with rakes 427 and 427 for leveling a farm scene.
By providing the left and right rakes 427, 427, it is possible to level the unevenness where the leveling device 5 cannot level the ground, further stabilize the seedling planting depth, and improve seedling growth. Become.

  The traveling vehicle body 2 is provided with a vehicle body rolling mechanism that causes the left and right front wheels 14 and 14 to expand and contract by a suspension mechanism (not shown) according to the unevenness of the field, etc., so that the vehicle body is in a horizontal posture with respect to the field scene. Yes. When the vehicle body rolling mechanism is operated, the seedling planting section 4 also needs to be rotated, so that the left rotation case 406L of the planting drive case 406 is provided with the rolling rotation shaft 417 as described above.

  When the traveling vehicle body 2 rolls and changes its posture, the seedling planting portion 4 rotates in the left-right direction with the rolling rotation shaft 417 as a fulcrum. A slope sensor 428 for detecting a change in posture of the seedling planting unit 4 at this time is provided on the top of the planting drive case 406, particularly just above the rolling rotation shaft 417. When the slope sensor 428 detects a change in posture, the rolling motor 423 is actuated, so that the seedling planting portion 4 is placed in a horizontal posture with respect to the field scene, so that the seedling planting direction is opposite to the rolling direction of the traveling vehicle body 2. The attaching part 4 is rotated.

  As a result, the traveling vehicle body 2 is in a posture along the farm scene, so that it can travel straight ahead and the seedling planting unit 4 is in a horizontal posture with respect to the farm scene. It becomes the same depth and improves the planting accuracy of the seedling.

  In addition, since the slope sensor 428 is provided almost immediately above the rolling rotation shaft 417, the amount of change in posture of the seedling planting unit 4 can be detected at a position close to the rolling center of the seedling planting unit 4, so that the rolling motor 423 At the time of operation, the seedling planting part 4 can be brought closer to the horizontal posture, and the seedling planting accuracy is improved.

  As shown in FIGS. 22 and 22, on the front side of the leveling support frame 403 and the plurality of planting transmission cases 405C, 405L, and 405R, a center float 38a and a left and right side float 38b that touch the field and level the unevenness. , 38b, and a center rotor 50 for leveling the front of the center float 38a, and left and right side rotors 51, 51 at the rear of the left and right sides of the center rotor 50 and in front of the left and right side floats 38b, 38b. Provide.

Further, the left and right ends of the center rotor 50 and the left and right side rotors 51 and 51 are connected by connecting transmission mechanisms 52 and 52, respectively.
As shown in FIG. 27, the longitudinal direction of the center rotor 50 and the left and right side rotors 51 and 51 are arranged in parallel with the left and right direction, and are supported by the left and right connecting transmission mechanisms 52 and 52 so as to be rotatable about the axis. Has been. The left and right connecting transmission mechanisms 52, 52 rotate the center rotor 50 and the left and right side rotors 51, 51 in conjunction with each other around an axis. Of the left and right coupling transmission mechanisms 52, the one provided on the left side of the machine body is provided with a drive input shaft 53 to which a driving force is input.

  As a result, the drive input shaft 53 and the PTO shaft 2p are arranged in the left-right direction of the rolling rotation shaft 417, so that the drive input shaft 53 and the PTO shaft 2p are hardly affected by the mutual rotational force.

  If the rotation directions of the drive input shaft 53 and the PTO shaft 2p are different from each other, the influence of the drive input shaft 53 and the PTO shaft 2p due to the mutual rotational force can be offset. 53 and the rotation of the PTO shaft 2p are stabilized, and seedling planting accuracy and leveling accuracy are improved.

The leveling device support mechanism 6 supports the leveling device 5 to the seedling planting unit 4. As shown in FIG. 29, the leveling device support mechanism 6 includes a pair of first leveling rotation arms 60 as leveling rotation arms and a leveling rotation arm provided between the pair of first leveling rotation arms 60. Second leveling rotation arms 61, 61, leveling lifting mechanism 62 (shown in FIG. 3), and horizontal maintaining mechanism 63.
One end of each of the first leveling rotary arm 60 and the second leveling rotary arm 61 is rotatably connected to the leveling support frame 59, and the other end is rotatably connected to the side rotors 51, 51 of the leveling device 5. Thus, the leveling device 5 is supported from behind.

  That is, the leveling device 5 is supported by the planting support frame 402, that is, the seedling planting unit 4 by the first and second leveling rotation arms 60, 61, 61, and the seedling planting unit lifting mechanism 31 It goes up and down together with the planting part 30.

  One end of the first leveling rotation arm 60 is rotatably connected to the left and right ends of the leveling support frame 59. As shown in FIG. 29, the first leveling turning arm 60 extends from the leveling support frame 403 toward the leveling device 5 when viewed from the side of the seedling transplanter. The other end of the first leveling rotation arm 60 is rotatably connected to the outer ends of the side rotors 51, 51 in the left-right direction.

The first leveling rotation arm 60 connects the left and right ends of the side rotors 51, 51 of the leveling device 5 to the left and right ends of the leveling support frame 403.
The other ends of the left and right second leveling rotation arms 61 and 61 are rotatably connected to the inner ends of the left and right side rotors 51 and 51 in the left and right direction. Thus, the left and right side rotors 51, 51 are supported by the first leveling rotary arm 60 and the left and right second leveling rotary arms 61, 61.

  As shown in FIG. 29, the leveling mechanism 62 includes a gear member 64, a lifting motor 65 as a rotational drive source, and a suspension arm 66. The gear member 64 is rotatably attached to a support plate 67 provided on a lower frame 420 constituting the planting support frame 402 of the seedling planting unit 4. Both surfaces of the support plate 67 are formed in parallel with the vertical direction and the front-rear direction.

  The gear member 64 is formed in a sector shape, and the center of rotation is arranged behind the tooth portion 64a provided on the arc-shaped outer edge portion. The lift motor 65 is attached to a support plate 67 fixed to the planting frame 402. The elevating motor 65 is rotatably provided on the support plate 67 and rotates a gear 68 engaged with a tooth portion 64 a of the gear member 64. Accordingly, the lifting motor 65 is configured to rotate the gear member 64 via the gear 68.

  The suspension arm 66 is formed in a rod shape, one end is slidably attached to the gear member 64, and the other end is rotatably attached to the central portion of one second leveling rotation arm 61. That is, the leveling mechanism 62 is attached to one second leveling rotation arm 61. The suspension arm 66 suspends the leveling device 5 from the planting frame 402 of the seedling planting unit 4 of the seedling planting device 3 via the second leveling rotation arms 61 and 61.

  The leveling mechanism 62 moves the suspension arm 66 up and down by the motor 65 rotating the gear member 64 and moves the leveling device 5 up and down via the second leveling rotation arms 61 and 61. The leveling mechanism 62 moves the leveling device 5 up and down over the lowermost position shown in FIG. 31 and the uppermost position shown in FIG. The leveling lift mechanism 62 is independent of the lifting link mechanism 16 and lifts and lowers only the leveling device 5 relative to the seedling planting part.

  At the lowest position, the leveling device 5 is aligned horizontally with the center float 38a and the left and right side floats 38b and 38b when viewed from the side of the traveling vehicle body 2. Further, at the uppermost position, the leveling device 5 is positioned above the center float 38a and the left and right side floats 38b and 38b when viewed from the side of the seedling transplanter, as shown in FIG.

  32, the leveling device 5 has a center float 38a and left and right side floats 38b as viewed from the side of the traveling vehicle body 2, as shown in FIG. 38 b and the horizontal float 38 b are positioned slightly above the center float 38 a and the left and right side floats 38 b and 38 b.

  The horizontal maintenance mechanism 63 maintains the posture of the traveling body 2 of the leveling device 5 in the front-rear direction, that is, the connecting transmission mechanism 52 of the leveling device 5 is parallel to the front-rear direction when viewed from the side. It is. As shown in FIG. 29, the horizontal maintenance mechanism 63 includes a contact protrusion 69, a coil spring 70 as an urging member, and a horizontal maintenance member 71.

  The contact protrusion 69 is attached to the outer surface in the left-right direction at the lower end of the suspension arm 66 and is provided on the suspension arm 66. The contact protrusion 69 is formed to protrude forward from the suspension arm 66. The contact protrusion 69 is formed such that the protrusion amount on the front side from the central suspension arm 66 in the vertical direction is larger than the protrusion amounts at both ends in the vertical direction.

  Moreover, the contact protrusion 69 is comprised with hard materials, such as a metal, hard resin, and carbon fiber, for example. Note that the hard material is a generic term for carbides, nitrides, borides, and certain oxides, which are substances using extremely high hardness. A contact surface 69 a with which a later-described roller 73 of the horizontal maintaining member 71 of the contact protrusion 69 contacts is formed in an arc shape when viewed from the side of the traveling vehicle body 2.

  One end of the coil spring 70 is attached to the contact member 100 provided at the front end of one of the coupling transmission mechanisms 52 that overlaps the suspension arm 66 in the vertical direction among the pair of transmission transmission mechanisms 52, 52 of the leveling device 5. It has been. One end of the coil spring 70 is attached to the upper end of the suspension arm 66.

  Thus, the coil spring 70 connects the front end portion of the one connection transmission mechanism 52 and the upper end portion of the suspension arm 66, and the one connection transmission mechanism 52, that is, the front end portion of the leveling device 5, upward and rearward. Energize.

  Further, the contact member 100 provided at the front end portion of the one connection transmission mechanism 52 is provided at a position in front of the suspension arm 66 of the one connection transmission mechanism 52 and protrudes upward from the one connection transmission mechanism 52. ing. Further, a contact roller 101 is provided as a contact rotating body that is rotatable about an axis in the left-right direction at the upper end of the contact member.

  In the contact member 100, when the leveling device 5 rises together with the seedling planting unit 4 by the lifting link mechanism 16 raising the seedling planting unit 4, the contact roller 101 contacts the lower link of the lifting link mechanism 16. And the raising / lowering link mechanism 16 raises the seedling planting part 4 from the state which this contact roller 101 contacted the lower link of the raising / lowering link mechanism 16, and the seedling planting part 4 is further raised with the leveling device 5. When the contact roller 101 contacts the lower link of the elevating link mechanism 16, the ascending contact member 100 rotates the leveling device 5 around the rear end as shown in FIGS. Is positioned below the left and right side rotors 51, 51.

  Thereby, even if the leveling apparatus 5 raises with the seedling planting part 4 by the raising / lowering link mechanism 16 raising the seedling planting part 4, the leveling apparatus 5 is below the raising / lowering link mechanism 16. Prevents damage from contact with links.

  The horizontal maintaining member 71 is attached to one connection transmission mechanism 52. The horizontal maintaining member 71 is in contact with the contact protrusion and maintains the horizontal posture of the left and right side rotors 51, 51, that is, the leveling device 5.

  As shown in FIG. 31, the horizontal maintaining member 71 includes a projecting member 72 projecting upward from one end on the inner side in the left-right direction of one coupling transmission mechanism 52, and an axial center in the left-right direction at the upper end of the projecting member 72. And a roller 73 as a rotatable rotating body. When the leveling device 5 is positioned at the lowermost position, the roller 73 can roll on the contact surface 69 a with the outer peripheral surface contacting the contact surface 69 a of the contact protrusion 69.

  Further, when the leveling device 5 is positioned slightly lower than the lowermost position shown in FIG. 31 or the lowermost position shown in FIGS. 31 and 32, the roller 73 of the contact surface 69 a of the contact protrusion 69 is provided. It touches a position below the center.

Further, when the leveling device 5 is positioned at the uppermost position, the roller 73 is positioned above the contact protrusion 69 as shown in FIG.
The retraction mechanism 72 retracts the horizontal maintenance member 69 of the horizontal maintenance mechanism 63 rearward when a load directed to the rear of the traveling vehicle body 2 along the horizontal direction acts on the horizontal maintenance member 69 of the horizontal maintenance mechanism 63, and the leveling device 5 is rotated upward.

  29 and 34, the retraction mechanism 72 includes a rotation support member 74 that rotatably supports the lower end portion of the horizontal maintaining member 69 on the suspension arm 66, a movement support member 75, and a biasing member 76 ( 34). The movement support member 75 is attached to the outer surface of the suspension arm 66, covers the rear end side of the horizontal maintaining member 69, and projects the contact surface 69a to the front side. The movement support member 75 allows the horizontal maintenance member 69 to rotate around the rotation support member 74 on the inside thereof, and restricts the horizontal maintenance member 69 from slipping forward.

  The movement support member 75 supports the upper end portion of the horizontal maintenance member 69 to be movable in the front-rear direction with respect to the suspension arm 66 by allowing the horizontal maintenance member 69 to rotate about the rotation support member 74. . The urging member 76 is supported in the movement support member 75. The urging member 76 is provided between the horizontal maintaining member 69 and the back wall of the movement support member 75 to urge the horizontal maintaining member 69 forward. The retraction mechanism 72 further includes a detection sensor that detects that the horizontal maintaining member 69 has retreated most backward.

  As shown in FIG. 29, the leveling device elevating mechanism 80 includes a support frame 81 attached to the seedling mount 37 of the seedling planting unit 30, a motor 82 attached to the support frame 81, a rotating arm 83, and the like. It has. The rotating arm 83 is supported by the support frame 81 so as to be rotatable around one end portion provided with a tooth portion 83a that meshes with a gear 84 attached to the output shaft of the motor 82.

  The other end of the pivot arm 83 is rotatably connected to one end of the suspension arm 66. In the leveling device lifting mechanism 80, the motor 82 rotates the gear 84 and the rotating arm 83, so that the suspension arm 66 and the support plate 67, that is, the entire leveling lifting device 62 are lifted and lowered. Independently, the leveling device 5 is raised and lowered.

  A control apparatus controls each component mentioned above which comprises a seedling transplanter. The control device includes, for example, shift control for controlling the hydraulic continuously variable transmission 15, lifting control of the seedling planting unit 30 by the seedling planting unit lifting mechanism 31, engine control for controlling the engine 11, and leveling by the leveling lifting device 62. The raising / lowering control of the apparatus 5 is performed. In the elevation control of the leveling device 5, the control device drives the motor 65 and adjusts the height of the leveling device 5 based on the operation position of the leveling height adjustment lever detected by the detection sensor. That is, the control device controls the motor 65 of the leveling lift device 62 so that the height of the leveling device 5 becomes the height set by the leveling height adjustment lever.

  In addition, the control device moves the seedling planting unit 30 to the non-working position by the hydraulic lifting cylinder 34 during turning during planting work on the field based on the detection result from the detection sensor that detects the steering angle of the handle 24. The seedling planting unit 30 is lowered to the ground work position during straight running during the planting operation on the field. When the control device raises the seedling planting portion 30 to the non-working position by the hydraulic lifting cylinder 34 during turning during planting work on the field, the angle-of-attack control sensor detects vertical movement of the center float 38a. In order to supply the hydraulic oil to the hydraulic elevating cylinder 34, the elevating valve is fully opened and the seedling planting part 30 is quickly raised to the non-working position.

  By doing so, it is possible to prevent the seedling transplanter from suddenly stopping during turning while working in the field. Further, the control device controls the motor 82 of the leveling device lifting mechanism 80 to raise and lower the leveling device 5 every predetermined time during planting work, and the leveling device 5 is always raised and lowered in small increments. The control mode to be switched can be switched. That is, the leveling device raising / lowering mechanism 80 always raises and lowers the leveling device 5 in a control mode in which the leveling device 5 is raised and lowered every predetermined time when the seedling planting unit 30 is positioned at the ground work position. The control mode to be switched can be switched.

  In the seedling transplanting machine described above, when seedlings are planted in the field, the seedling planting device 3 is lowered to the ground work position (seedling planting position) by operating various operation levers of the operator. In the seedling transplanter, the leveling device 5 is positioned slightly above the lowermost position shown in FIG. 5 or the lowermost position shown in FIG. 32 by the operator's operation of the leveling height adjustment lever. Then, the seedling transplanter smoothes the surface of the field by rotating the rotors 50 and 51 of the leveling device 5 while traveling in the field. In the seedling transplanting machine, while the rotation support part 36b of the seedling planting part 30 rotates around the center part, the transplanting ridges 36c rotate at both ends of the rotation support part 36b, and the seedlings are planted in the field.

  When the seedling transplanter plantes seedlings in the field, the leveling device 5 is positioned slightly above the lowermost position shown in FIG. 31 or the lowermost position shown in FIG. It contacts the position below the center of the contact surface 69a of 69. When the seedling transplanter plantes seedlings in the field, the center rotor 50 sinks into a recess or the like in the field, and when the leveling device 5 tries to rotate so that the center rotor 50 is directed below the side rotor 51, the roller 73 comes into contact. An attempt is made to roll upward on the surface 69a.

  At this time, since the roller 73 is in contact with a position below the center of the contact surface 69 a of the horizontal maintaining member 69, the rolling of the roller 73, that is, the center rotor 50 is directed downward from the side rotor 51. The rotation is restricted by the contact surface 69 a of the horizontal maintaining member 69.

  Further, even if the center rotor 50 is pushed upward by a convex portion or the like of the field when the seedling transplanter transplants the seedling in the field, the roller 73 is in contact with the contact surface 69a of the horizontal maintaining member 69, so the center rotor The rotation of the leveling device 5 in the direction in which 50 is directed upward is restricted by the roller 73, the horizontal maintaining member 69, and the like. Thus, the horizontal maintenance mechanism 63 maintains the posture in the front-rear direction of the leveling device 5 horizontally when the seedling transplanter plants a seedling in the field.

  Further, when the seed rotor transplanter plantes seedlings in the field, if a load is applied to the center rotor 50 from the convex portion of the field or the like to the rear, the horizontal maintaining member 69 resists the biasing force of the biasing member 76 by this load. The upper end of the evacuates backward. Then, the seedling transplanting machine rotates the leveling device 5 upward so that the roller 73 rolls upward on the contact surface 69a and the center rotor 50 faces upward.

  In addition, when the detection sensor detects that the horizontal maintenance member 69 has been retracted most backward, the seedling transplanter controls the motor 82 of the leveling device lifting mechanism 80 to raise the leveling device 5 for each leveling device 62. The seedling transplanter controls the motor 82 of the leveling device lifting mechanism 80 and controls the leveling device 5 together with the leveling lifting device 62 to the original position when the detection sensor no longer detects that the horizontal maintenance member 69 has been retracted most backward. To lower.

  When the seedling transplanter finishes planting the seedling in the field, the leveling device 5 is positioned at the uppermost position shown in FIG. 33 by the operator's operation of the leveling height adjustment lever. The leveling device 5 is raised to the non-working position together with the seedling planting unit 30 by the lifting mechanism 31. And the seedling transplanter moves between farm fields or moves outside the farm fields.

  As described above, according to the configuration of the seedling transplanter of the present embodiment, the lower frame 39 supports the leveling device 5 from the rear via the rotating arms 60 and 61. For this reason, when the leveling device 5 comes into contact with the convex portion of the agricultural field, the lower frame 39 supports the force pushed from the convex portion of the agricultural field via the rotating arms 60 and 61, and the longitudinal direction of the leveling device 5. Will be maintained. For this reason, since the seedling transplanting machine can suppress the leveling device 5 from entering the concave portion of the farm field, the leveling device 5 can be prevented from being damaged.

  In addition, since the lower frame 39 supports the entire leveling device 5 from the rear, the seedling transplanter can suppress only a part of the leveling device 5 from being lifted by a force pushed by the convex portion of the field, In particular, the convex part of the field can be leveled reliably.

  Further, in the seedling transplanter, since the horizontal maintenance mechanism 63 maintains the posture of the leveling device 5 horizontally, even if the seedling planting unit 30 is lifted and lowered at the ground work position, the posture of the leveling device 5 is kept horizontal, During the work, the leveling device 5 can be prevented from sinking into the field due to its own weight or the like, or entering the field. Therefore, the seedling transplanting machine can surely level the surface of the field without damaging the leveling device 5, suppresses the surface of the field from being roughened, and improves leveling accuracy and seedling planting accuracy. , Planting depth of seedling can be stabilized.

  The seedling transplanter includes a pair of outer rotation arms 60 as leveling rotation arms and an inner rotation arm 61 provided between the pair of outer rotation arms 60. For this reason, the seedling transplanting machine supports the leveling device 5 at a plurality of positions in the left-right direction, and the leveling device 5 is submerged into the field or lifted only partially by a force pushed from the convex portion of the field. Can be reliably suppressed. In addition, the seedling transplanter can support the leveling device 5 by the outer turning arm 60 and the inner turning arm 61 and can adjust the working height of the entire leveling device 5 by the leveling lifting device 62. Therefore, since the contact amount of the leveling device 5 can be changed in accordance with work conditions such as soil quality of the field, the leveling accuracy can be improved.

  In addition, since the seedling transplanting machine has the leveling lifting device 62 attached to the inner turning arm 61, the leveling device 5 is lifted and lowered at a position near the center in the left-right direction of the traveling vehicle body 2. For this reason, the seedling transplanter can move up and down while maintaining the leveling device 5 in a horizontal posture in the left-right direction. Therefore, the seedling transplanting machine can surely level the surface of the field without damaging the leveling device 5.

  The seedling transplanter includes a suspension arm 66 in which the leveling device 62 is attached to the inner turning arm 61 and the leveling device 5 is suspended from the planting frame 35. The height of 5 can be changed reliably. Therefore, except during the leveling work, the leveling device 5 can be raised to reliably prevent the surface of the field from becoming rough.

  In addition, when the seedling transplanting machine lowers the leveling device 5, the roller 73 of the posture maintaining member 71 comes into contact with the horizontal maintaining member 69 from which the center of the horizontal maintaining mechanism 63 protrudes most. For this reason, when the leveling device 5 is lowered, the leveling device 5 moves in the direction in which the center rotor 50 is directed downward by the roller 73 of the posture holding member 71 coming into contact with the horizontal maintaining member 69. .

  Further, in the seedling transplanter, the horizontal maintenance mechanism 63 includes a coil spring 70 that biases the connection transmission mechanism 52 upward. For this reason, the leveling device 5 is suspended by the suspension arm 66 and the coil spring 70. Therefore, the seedling transplanter can maintain the entire leveling device 5 in a horizontal posture in the front-rear direction, can level the surface of the field without damaging the leveling device 5, and the planting depth of the seedling is stabilized. .

  In the seedling transplanter, the center rotor 50 and the side rotor 51 are connected by the connecting transmission mechanism 52, so that the leveling device 5 is maintained horizontal by providing only one set of the horizontal maintaining member 69 and the posture maintaining member 71. And increase in the number of parts can be suppressed.

  In the seedling transplanter, since the horizontal maintenance member 69 is made of a hard material, deformation of the horizontal maintenance member 69 can be suppressed, and the posture of the leveling device 5 can be reliably maintained horizontal. Further, since the contact surface 69a of the horizontal maintaining member 69 is formed in an arc shape, when the leveling device 5 is lowered, the roller 73 of the posture maintaining member 71 can be prevented from being separated from the horizontal maintaining member 69, and the leveling device The posture of 5 can be reliably maintained horizontal.

  Moreover, since the horizontal maintenance mechanism 63 will retract | save when the load which goes back to the horizontal maintenance mechanism 63 acts on the seedling transplanter, the leveling apparatus 5 can be rotated upwards. For this reason, it can suppress that the leveling raising / lowering apparatus 62 and leveling apparatus 5 itself are damaged by load etc. Thus, the seedling transplanter can surely level the surface of the field without damaging the leveling device 5.

  In the seedling transplanter, the rear end portion of the posture maintaining member 71 of the horizontal maintenance mechanism 63 is in contact with the horizontal maintenance member 69 biased forward, so that the leveling device 5 is horizontal with respect to the surface of the field. The center rotor 50 is restricted from being rotated downward relative to the position. Therefore, it can suppress that the center rotor 50 roughens the surface of a farm field, and can improve the planting accuracy of a seedling and can stabilize planting depth.

  In addition, the seedling transplanting machine receives a load when the center rotor 50 comes into contact with the surface of the field, etc., and when the force that the posture holding member 71 pushes the horizontal maintenance member 69 backward becomes a certain level or more, the horizontal maintenance member Since the upper end portion of 69 moves backward against the urging force of the urging member 76, damage such as bending of the suspension arm 66 can be suppressed.

  In the seedling transplanter, the scattering prevention member 85 includes the protective body 87 that connects the front sides of the support 86 to each other, so that the muddy soil can be prevented from scattering forward due to the rotation of the center rotor 50. Therefore, it is possible to suppress the mud from scattering to the worker on the traveling vehicle body 2.

  Moreover, since the scattering prevention member 85 has open | released the upper direction and the back of the center rotor 50, the seedling transplanter can suppress that mud is clogged between the center rotor 50 and the scattering prevention member 85, and the leveling device 5 The driving efficiency can be prevented from being lowered without hindering driving, and the leveling performance of the leveling device 5 can be improved.

  Since the seedling transplanter has the second protective body 89 disposed behind and above the first protective body 88, it is possible to more reliably suppress the scattering of mud from the center rotor 50 to the front side. It is possible to suppress the mud from scattering to the worker on the vehicle body 2.

  In addition, since the seedling transplanter opens the upper part between the first protective body 88 and the second protective body 89, it is confirmed that mud is clogged between the first protective body 88 and the second protective body 89. It is possible to suppress the decrease in work efficiency without impeding the driving of the leveling device 5, and the leveling performance of the leveling device 5 can be improved.

  Moreover, since the seedling transplanter includes the leveling device lifting mechanism 80 that lifts and lowers the leveling device 5 together with the leveling device 62, the range in which the leveling device 5 can be raised and lowered can be widened. Even if you step on a lump of foreign matter, you can retreat upward. Therefore, it is possible to prevent the leveling device 5 and the leveling lifting device 62 from being damaged.

  Moreover, since the leveling device raising / lowering mechanism 80 raises / lowers the leveling device 5 in a predetermined control mode, the seedling transplanter can perform leveling work while escaping foreign matters such as scum accumulated below the leveling device 5. . Therefore, it can suppress that a foreign material prevents leveling of the unevenness | corrugation of a field, and can improve leveling property.

  Outside the auxiliary step 27 on the left side of the vehicle body, a spare seedling frame 19 configured by providing a plurality of preliminary seedling platforms 20u, 20m, 20d... It is supported by a main support frame 24 and a sub support frame 25 fixed to the part. The base support frame 23 has a lower end bent, and the bent portion goes around the lower side of the auxiliary step 27 and is fixed to the bracket 26 of the vehicle body frame. The main support frame 24 and the sub-support frame 25 that are fixed to the upper end portion of the basic support frame 23 and the front and rear ends thereof are erected substantially vertically.

Further, outside the auxiliary step 27 on the right side of the vehicle body, there is provided a fixed fixed seedling placement unit 28 that is configured not to rotate and on which a spare seedling is placed.
A switching device 21 is fixed to the upper end portion of the main support frame 24, and the main link arm 41 that connects the three preliminary seedling platforms 20u, 20m, and 20d is rotated by the switching device 21, whereby a preliminary seedling frame is obtained. 19 is configured to be switchable between a laminated form and a developed form.

  Since the switching device 21 is fixed to the upper end portion of the main support frame 24, it is possible to secure the rotation trajectory of the link mechanism of the preliminary seedling frame 19 while suppressing the vertical length of the main support frame 24. Since it is prevented that the position of the preliminary seedling mounting bases 20u, 20m, and 20d becomes too high and it becomes difficult to load and remove seedlings, work efficiency is improved.

  As shown in FIG. 5, the switching device 21 is configured to be covered with a switching unit cover 31 in order to prevent an operator from contacting the semicircular gear 32 constituting the switching device 21.

  Since the switching unit cover 31 shown in FIG. 5 is configured to expose the upper portion of the switching actuator 22 that operates the gear 32, the switching device 21 is configured to be compact. It is also possible to form a cover portion on the switching unit cover 31 so as to cover the entire switching actuator 22.

  In addition, an empty seed box storage portion 33 for storing an empty seed box, a seedling plate, and the like is fixed to the main support frame 24 and the sub support frame 25 and provided inside the vehicle body. The empty seedling box housing portion 33 is configured by combining metal bars in the present case, but may be configured using other materials. In addition, in FIG. 1 to FIG. 4, illustration of the empty seedling box housing portion 33 is omitted.

  By providing the empty seedling box housing part 33, empty seedling boxes and seedling boards can be stored, so that the seedling boxes and seedling boards are blown off by the wind and fall to the field. This eliminates the need for workers to collect and improves work efficiency.

  Further, by providing the empty seedling box accommodating portion 33 between the preliminary seedling frame 19 and the bonnet 13, the operator can transfer the seedling box and the seedling scooping plate to the empty seedling box accommodating portion 33 without moving on the vehicle body. Since it can be accommodated, the labor of the operator is reduced.

  If the empty seedling box accommodating part 33 is arranged outside the vehicle body, the empty seedling box accommodating part 33 cannot be moved to the wall due to the protrusion of the empty seedling box accommodating part 33, and the distance from the driver to the empty seedling box accommodating part 33 is increased. Therefore, it is reasonable to arrange the seedling box and the seedling plate on the inner side of the vehicle body as shown in the first embodiment. Will improve.

  In addition, the vehicle body of the seedling transplanter according to the first embodiment corresponds to an example of the traveling vehicle body of the present invention. The main support frame 24 and the sub support frame 25 correspond to an example of the support member of the present invention. The switching device 21 is an example of the switching device of the present invention, and the switching unit cover 31 is an example of the cover of the present invention. Furthermore, the empty seedling box housing part 33 corresponds to an example of the housing member of the present invention.

Next, the connection configuration between the reserve seedling frame 19 and the switching device 21 and the operation of the reserve seedling frame 19 will be described.
FIG. 6 shows a side view of the preliminary seedling frame 19 in the laminated form of the first embodiment as seen from the outside of the seedling transplanter, and FIG. 7 shows a side view of the spare seedling frame 19 seen from the inside of the seedling transplanter. FIG. 8 shows a side view of the preliminary seedling frame 19 in the unfolded form of the first embodiment as seen from the outside of the seedling transplanter, and FIG. 9 shows a side view seen from the inside of the seedling transplanter.

  As shown in FIG. 6, the switching device 21 according to the first embodiment has a front and rear width that falls within the range of the front and rear widths of the preliminary seedling platforms 20u, 20m, and 20d in a side view in the stacked form of the preliminary seedling frames 19. . By making the front-rear width of the switching device 21 shorter than the front-rear width of the spare seedling platforms 20u, 20m, 20d, the switching device 21 protrudes from the front-rear width of the preliminary seedling platforms 20u, 20m, 20d in a stacked configuration. There is no, and it can be set as a compact structure.

In addition, the front-rear width of the switching device 21 may be substantially the same as the front-rear width of the preliminary seedling mounts 20u, 20m, 20d.
As shown in FIGS. 6 and 7, the three preliminary seedling platforms 20 u, 20 m, and 20 d are connected to the main link arm 41 at intervals. The spare seedling stage 20u and the spare seedling stage 20m are connected by a first sub-link arm 42 on the front side, and the preliminary seedling stage 20m and the spare seedling stage 20d are on the second sub-link arm 43 on the rear side. Are connected by

The preliminary seedling stage 20u is connected to the first sub-link arm 42 via a rotating part 46 so as to be rotatable, and is connected to the main link arm 41 via a rotating part 47 so as to be rotatable.
The preliminary seedling stage 20m is connected to the first sub-link arm 42 via a rotating part 48 so as to be rotatable, and connected to the main link arm 41 via a freely rotating shaft 45. The second sub link arm 43 is connected to the second sub link arm 43 through a rotating portion 49 so as to be freely rotatable.

The preliminary seedling stage 20d is connected to the main link arm 41 via a rotating part 50 so as to be rotatable, and connected to the second sub-link arm 43 via a rotating part 51.
A main rotating shaft 44 that rotatably attaches the main link arm 41 to the front main support frame 24 is provided at a central portion of the main link arm 41 and at a position ahead of the driven rotating shaft 45. .

The main rotation shaft 44 is an example of the shaft of the present invention, and a portion where the main rotation shaft 44 is connected to the main link arm 41 corresponds to an example of a rotation center portion of the link mechanism of the present invention.
The second sub link arm 43 is connected to the upper end portion of the sub support frame 25 via a rotating shaft 52 at a portion close to the spare seedling stage 20m, and the second sub link arm 43 is centered on the rotating shaft 52. The two sub link arms 43 are configured to be rotatable.

  The main rotation shaft 44 is configured to rotate by driving the switching actuator 22 of the switching device 21, and the main link arm 41 rotates with the rotation of the main rotation shaft 44. Along with the rotation, the preliminary seedling stage 20u and the preliminary seedling stage 20d connected to both ends thereof are regulated by the first sub-link arm 42 and the second sub-link arm 43, respectively, while maintaining a substantially horizontal state. Move.

  In addition, as the main link arm 41 rotates, the spare seedling table 20m connected by the driven rotation shaft 45 is also substantially horizontal while being regulated by the first sub link arm 42 and the second sub link arm 43. Move while maintaining state.

  In the stacked form of the spare seedling frame 19 shown in FIG. 6, when the main link arm 41 rotates counterclockwise, the preliminary seedling stage 20 u moves upward while descending, and moves to the front. After descent, 20d moves backward while ascending. And the reserve seedling frame 19 becomes the expansion | deployment form shown in FIG.

FIG. 15 shows a plan view of the preliminary seedling frame 19 in the unfolded form. Here, illustration of parts other than the reserve seedling frame 19 and the switching device 21 is omitted.
The main link arm 41, the first sub-link arm 42, and the second sub-link arm 43 are arranged at equidistant positions parallel to the preliminary seedling mounts 20u, 20m, and 20d, as shown in FIG. In the unfolded form, these link arms 41, 42, and 43 are in an overlapping state.

  Moreover, as shown in FIG.5 and FIG.15, it arrange | positions in order of the switching apparatus 21, each link arm 41, 42, 43, the reserve seedling mounting bases 20u, 20m, and 20d toward the vehicle body outer side from the operation part 10 side. Therefore, there is no member that obstructs the movement of the seedlings placed on the preliminary seedling placing stands 20u, 20m, and 20d, and the seedling mat can be easily loaded.

  In conventional riding type rice transplanters, a stopper is provided for determining the stop position of the stored seedling placement member, so that each time the spare seedling placement member is switched to the deployed form or the stacked form, the operating state of this stopper is manually changed. There is a problem that the work efficiency is lowered because it is necessary to be released, and there is a problem that the configuration of the preliminary seedling mounting member is complicated because the stopper must be switched between the operating state and the non-operating state.

  And when the preliminary seedling placement member is switched to the deployed form, a receiving member is provided to prevent the loaded seedling from falling from the front side and the rear side of the preliminary seedling placement member. Because of the protruding shape, when loading seedlings on the spare seedling mounting member, the operator must load the seedling avoiding the upper part of the receiving member, so the seedling cannot be easily loaded and the efficiency of the seedling replenishment work There is a problem that decreases.

  Furthermore, since there is no conveyance auxiliary rotating body or the like for assisting the movement of the seedling between the spare seedling placement members, there is a problem that the labor required for the rearward movement of the seedling increases and the work efficiency decreases.

  As shown in FIGS. 10, 12, and 15, a pair of front protrusions 38a1, 38b1, and 38c1 protruding forward at the front ends of the first, second, and third preliminary seedling platforms 20u, 20m, and 20d. Are formed, and rear projecting portions 38a2, 38b2, and 38c2 projecting rearward are formed at the center of the rear end portion, respectively. Accordingly, when the first, second, and third preliminary seedling platforms 20u, 20m, and 20d are in the deployed form, the rear protrusions 38a2 and 38b2 of the preliminary seedling platforms 20u and 20m located on the front side of the machine body are located on the rear side of the machine body. It arrange | positions in the position which overlaps with the front side protrusion parts 38b1 and 38c1 of the reserve seedling stand 20m and 20d which are located in a side view. The front protrusions 38a1, 38b1, and 38c1 are examples of front stoppers, and the rear protrusions 38a2, 38b2, and 38c2 are examples of rear stoppers.

  Therefore, when the first, second, and third preliminary seedling platforms 20u, 20m, and 20d are arranged in the front-rear direction, the first, second, and third preliminary seedling platforms 20u, 20m, and 20d are moved forward and backward. Since they can be arranged in the direction, the seedling boxes loaded on the preliminary seedling platforms 20u, 20m, and 20d can be smoothly moved to the rear side, and the work efficiency is improved as compared with the prior art.

  Then, the preliminary seedling placement members 20u, 20m, and 20d are switched to the expanded form or the stacked form without switching the front side stopper parts 38a1, 38b1, 38c1 and the rear side stopper parts 38a2, 38b2, 38c2 to the active state or the non-active state. Therefore, it is possible to prevent the configuration of the spare seedling placement members 20u, 20m, and 20d from becoming complicated, and to improve work efficiency.

  As shown in the side views of FIGS. 10 and 12, the rear protrusions 38a1, 38b1, and 38c1 of the first, second, and third preliminary seedling platforms 20u, 20m, and 20d have a rear upward inclination shape (rear upward inclination part). A guide surface is formed, and the guide surface is made higher than the seedling placement surfaces of the preliminary seedling placement stands 20u, 20m, and 20d.

And in a development form, a rear side stopper part is arranged behind the guide surface or the guide surface in a side view.
Further, the rear protrusions 38a2, 38b2, and 38c2 of the first, second, and third preliminary seedling platforms 20u, 20m, and 20d are made higher than the seedling mounting surfaces of the preliminary seedling platforms 20u, 20m, and 20d, and It is the same as the upper surface of the front protrusions 38a1, 38b1, 38c1, or lower than the upper surface.

  As described above, when the first projecting portions 38a1, 38b1, and 38c1 are rear-upward inclined portions, when the first, second, and third preliminary seedling platforms 20u, 20m, and 20d are in the expanded state, the front preliminary seedlings When moving a seedling box or the like from the mounting bases 20u, 20m to the rear spare seedling mounting bases 20m, 20d, the seedling box can be placed on the rear-upward inclined portion and moved rearward. And the work efficiency is improved as compared with the prior art.

  Further, a front stopper portion formed at the rear portion of the guide surface of the front protruding portions 38a1, 38b1, and 38c1 and a rear stopper portion formed at the rear protruding portions 38a2, 38b2, and 38c2 are respectively provided as the preliminary seedling platforms 20u, 20m, and 20d. When the first, second, and third preliminary seedling platforms 20u, 20m, and 20d are stacked, the front protrusions 38a1, 38b1, 38c1, and the rear protrusion 38a2 are formed. , 38b2 and 38c2, it is possible to prevent the seedling boxes placed on the preliminary seedling platforms 20u, 20m, and 20d from moving back and forth, so that the seedling boxes fall downward from the preliminary seedling platforms 20u, 20m, and 20d. This eliminates the need to pick up the fallen seedling box and improves the work efficiency.

  Between the left and right of the pair of front protrusions 38a1, 38b1, 38c1 of each of the spare seedling platforms 20u, 20m, 20d and at the bottom of the preliminary seedling platforms 20u, 20m, 20d, the front preliminary seedling platforms 20u, 20m Receiving members 38a3, 38b3, 38c3 for receiving the rear projecting portions 38a2, 38b2, etc. are provided respectively, and the receiving members 38a3, 38b3, 38c3 are provided in the space between the pair of front projecting portions 38a1, 38b1, 38c1. Protrusively formed.

  In addition, receiving members 38a3, 38b3, 38c3 are provided on one of the front side protruding portions 38a1, 38b1, 38c1 and the rear side protruding portions 38a2, 38b2, and the front side protruding portions 38a1, 38b1, 38c1 are provided by the receiving members 38a3, 38b3, 38c3. And the other of the rear protrusions 38a2 and 38b2.

  With the above-described configuration, the receiving members 38b3 and 38c3 are provided between the left and right sides of the front protrusions 38b1 and 38c1 of the respective reserve seedling platforms 20m and 20d, and the rear protrusions 38a2 of the front preliminary seedling platforms 20u and 20m. , 38b2 so that the preliminary seedling platforms 20u, 20m, and 20d are not lowered too much, and the deployed seedling platforms 20u, 20m, and 20d are surely aligned at substantially the same height. Therefore, the seedling box can be easily loaded and the work efficiency can be improved as compared with the prior art.

  Further, by providing the receiving members 38a3, 38b3, 38c3 at the bottom of the preliminary seedling platforms 20u, 20m, 20d, the upper ends of the rear protrusions 38a2, 38b2, 38c2 are the upper ends of the front protrusions 38a1, 38b1, 38c1. Since the seedling boxes placed on the front protrusions 38a1, 38b1, and 38c1 having the rear-upward inclined portions are smoothly moved, the work efficiency is improved as compared with the conventional case. To do.

  In addition, first, second, and third partition walls 38a4, 38b4, and 38c4 that prevent the seedling box from dropping are provided at four locations on the front and rear sides of the first, second, and third preliminary seedling platforms 20u, 20m, and 20d. Each is arranged.

  Furthermore, the rotation fulcrum 44 of the second moving link member 39b may be provided coaxially with the rotation shaft 45 of the second preliminary seedling stage 20m. In this case, it becomes the structure where the center 2nd seedling stand 20m does not move back and forth.

  14 (a) and 14 (b) are side views showing the seedlings moving on the preliminary seedling mounting bases 20u, 20m, and 20d in the unfolded form, and FIG. 14 (c) is a plan view in which the seedlings are omitted. It is. 14C and 14D are a plan view provided with an auxiliary transport rotating body for assisting the transport of seedlings, and a side view of the main part.

  Of the three protrusions 20u, 20m, and 20d, the front protrusions 38a1, 38b1, and 38c1 have front protrusions 38b1, 38c1 of the second and second preliminary seedling support 20m and 20d. Rotation assisting rotating bodies 47b and 47c that rotate to assist the seedling transportation are arranged.

At this time, the upper surfaces of the auxiliary conveyance rotating bodies 47b and 47c are configured to protrude upward from the upper part of the rear upward inclined surface of the front protrusions 38b1 and 38c1.
By providing the conveyance auxiliary rotators 47b and 47c in the front protrusions 38b1 and 38c1, the worker can put seedlings on the second preliminary seedling stage 20d and the third preliminary seedling stage 20d when in the deployed form. When pushing and moving, the force required to move the seedling can be reduced, so the labor of the operator is reduced.

Then, since the upper surfaces of the conveyance auxiliary rotators 47b and 47c are positioned above the front protrusions 38b1 and 38c1, the auxiliary conveyance rotators 47b and 47c act reliably.
FIG. 17 is an explanatory diagram showing the structure of the switching device 21.

  As shown in FIG. 17, the main support frame 24 is arranged inside the vehicle body, and the main link arm 41 is arranged outside the main support frame 24. A fixed support plate 58 is fixed to the upper end portion of the main support frame 24, and the switching actuator 22 is fixed to the fixed support plate 58.

  The main rotation shaft 44 is fixed to the main link arm 41, and is also fixed to the gear 32 so as to pass through the center position of the arc in which the tooth portion 55 is formed. The main rotation shaft 44 is rotatably connected to the main support frame 24, and the main rotation shaft 44, the gear 32, and the main link arm 41 are configured to rotate integrally.

  As shown in FIG. 17, the main support frame 24, the switching actuator 22, the gear 32, and the main link arm 41 are arranged in this order from the inside to the outside of the vehicle body. Further, as shown in FIG. A spare seedling frame 19 is connected to the outside.

  With the above configuration, the switching device 21 is positioned on the front side of the main link arm 41, the first sub link arm 42, and the second sub link arm 43 as viewed from the worker working on the auxiliary step 27. As a result, it is possible to prevent the hands and arms of the worker from colliding with the rotating main link arm 41, first sub link arm 42, and second sub link arm 43, so that work safety is improved.

  As shown in FIG. 5, the switching actuator 22 constituting the switching device 21, the rotating gear 61 and the gear 32 pivotally attached to the output shaft (not shown) of the switching actuator 22, together with the upper part of the main support frame 24, The switching unit cover 31 covers the structure.

  In addition, the said switching part cover 31 is good also as a structure covered in the upper part of the switching apparatus 21, for example by making it the box-shaped shape by which the downward direction was open | released. Moreover, it is good also as a box-shaped shape by which the side surface was open | released, covering the switching device 21 from the side surface by the side of the main support frame 24, and attaching a lid | cover to the side part opened after that.

  When the switching unit cover 31 is structured to be detachably attached from above the switching device 21 in a box shape having an open bottom, the switching unit cover 31 can be easily detached, so that maintainability is improved.

Note that the size of the switching device 21 can be made more compact as the switching actuator 22 is arranged closer to the gear 32.
The main support frame 24 may have a hollow pipe shape, and a harness that supplies power to the switching actuator 22 may be connected to the switching actuator 22 through the main support frame 24. With this configuration, it is possible to prevent the harness that supplies power to the switching actuator 22 from being entangled even when the main seedling frame 19 faces the inside of the vehicle body when the main support frame 24 is rotated.

  Further, an operation member for switching the stacking form and the unfolding form of the preliminary seedling frame 19, that is, a switching operation switch 73 (shown in FIG. 16) for driving the switching actuator 22 is provided on the handle post 30 at the base of the steering handle 18. You may arrange. By providing a switching operation switch 73 on the handle post 30, the driver can operate the driving unit 10 to switch the state of the spare seedling frame 19.

In addition, since the switching operation switch 73 is disposed at a position that cannot be reached unless a hand is stretched while sitting on the driver's seat 12, the possibility of erroneous operation is reduced.
Alternatively, the switching operation switch 73 for switching the state of the preliminary seedling frame 19 may be provided on the handle post 30 and at the front position of the bonnet 13. By adopting such a configuration, an assistant other than the driver can be operated, and for example, the rotation operation of the spare seedling frame 19 can be stopped when it is felt dangerous.

Similarly, a switching operation switch 73 for switching the state of the preliminary seedling frame 19 may be provided in the preliminary seedling frame 19 or the switching device 21.
FIG. 10 is a side view showing the reserve seedling frame 19 in a stacked form provided with stop plates 73a1 and 73a2, and FIG. 11 is a main part side view showing the mounting positions of the stop plates 73a1 and 73a2. FIG. 12 is a side view showing the reserve seedling frame 19 in an unfolded form provided with the stop plates 73a1 and 73a2, and FIG. 13 is a side view of the main part showing the attachment positions of the stop plates 73a1 and 73a2.

  Further, FIG. 16 shows that when the spare seedling frame 19 is operated and the main link arm 41, the first and second sub link arms 42, 43 contact the stop plates 73a, 73a2, and a load is generated on the switching actuator 22, the switching actuator It is an operation control block diagram which shows that 22 stops.

  When the operation switch 73 is operated to switch the preliminary seedling frame 19 to the stacked form and the deployed form, the main seeding arm 19 contacts the main link arm 41, the first and second sub link arms 42, 43, and further rotates. Stop plates 73a1 and 73a2 to be regulated are provided. The stop plates 73a1 and 73a2 are provided on the side surfaces of the center preliminary seedling stage 20m and the lower preliminary seedling stage 20d in a stacked form.

  As shown in FIGS. 10 and 11, when the reserve seedling frame 19 is in a stacked state, the main link arm 41 comes into contact with the stop plate 73a2 located on the lower side to restrict further rotation, and this rotation restriction is performed. By continuing, when the load more than a fixed value arises in the switching actuator 22, or when it becomes an overheated state, the control apparatus 100 stops the switching actuator 22.

  Further, as shown in FIGS. 12 and 13, when the preliminary seedling frame 19 is in the deployed form, the main link arm 41 comes into contact with the stop plate 73a1 located on the front side to restrict further rotation, and this rotation restriction is prevented. By continuing, when the load more than a fixed value arises in the switching actuator 22, or when it becomes an overheated state, the control apparatus 100 stops the switching actuator 22.

  As described above, the switching actuator 22 is stopped via the control device 100. However, the switching actuator 22 is an electric motor, and an energization path using the energization switching member 92 is disposed inside the electric motor. A configuration may be adopted in which the energization switching member 92 is bent and forcibly switched from the energized state to the non-energized state when the temperature exceeds a certain temperature due to a load.

  With the above configuration, when the spare seedling frame 19 is switched to the stacked form or the deployed form, the operator does not have to stop the switching actuator 22 by operating the switching operation switch 73, so that the operator can concentrate on other operations. Work efficiency is improved more than before.

  In addition, when the preliminary seedling frame 19 is in a stacked form or an unfolded form, the main moving link arm 41 comes into contact with the stop plates 73a1 and 73a2, so the main link arm 41, the first and second sub-links are caused by the vibration of the fuselage. The link arms 42 and 43 are prevented from moving and the preliminary seedling frame 19 is prevented from shaking back and forth, so that the seedling is prevented from falling, and wear of the preliminary seedling frame 19 and other components due to the shaking is reduced.

  Furthermore, when the spare seedling frame 19 is switched to the stacked form or the deployed form, components such as a switch for stopping the switching actuator 22 and a circuit can be omitted, so that the number of parts can be greatly reduced and the configuration can be reduced. Be concise.

18A and 18B, the configuration of the switching device 21 of the present case will be described.
A cover plate 78 constituting the switching device 21 is provided, and an auxiliary plate 79 is mounted at a position closer to the outside of the vehicle body than the gear 32 that moves the main link arm 41. Then, a holding plate 80 is mounted between the left and right of the cover plate 78 and the auxiliary plate 79, the holding plate 80 is extended to the auxiliary plate 79 side and supported by the auxiliary plate 79, and the auxiliary plate 79 and the holding plate 80, the switching actuator 22 is supported from the left and right.

  In the switching device 21 configured as described above, the holding plate 80 is provided between the left and right of the cover plate 78 and the auxiliary plate 79, and the switching actuator 22 is supported from the left and right by the holding plate 80 and the auxiliary plate 79, whereby the main link arm 41. When the first and second sub link arms 42 and 43 contact the stop plates 73a1 and 73a2 and apply a load, even if a force that the switching actuator 22 tries to move is applied to the holding plate 80, the force is covered. Since it can be received by the plate 78 and the holding plate 80, the switching actuator 22 is accurately supported with sufficient strength.

  Further, since the distance between the switching actuator 22 and the gear 32 can be prevented by preventing the switching actuator 22 from moving, the adjustment work of the switching device 21 becomes unnecessary, and the work efficiency is improved.

  As described above, by using the spare seedling frame 19 that can be switched between the stacked form and the deployed form, the seedling mat and seedling box are moved to the seedling transplanter from outside the field by moving on the spare seedling platforms 20u, 20m, and 20d. Since the loading operation can be performed, the loading operation of the seedling becomes easy, and the labor of the operator is reduced. However, when planting with the seedling transplanter of this configuration, since the fertilizer is supplied to the field by the fertilizer application device 17, it is necessary to periodically replenish the fertilizer with the fertilizer, which is used for the supplement work. It is also necessary to load fertilizer bags.

  The fertilizer bag has a weight of about 20 kg per bag if it is of a commercially available general size. In the conventional work, the worker holds the fertilizer bag and moves in the field and replenishes the fertilizer application device 17 after being raised on the seedling transplanter. However, the weight of the operator is about 20 kg. When walking in the paddy field in such a state, it becomes easy for the feet to be taken by the mud.

  In order to solve the above problems, the fertilizer bags are placed on the preliminary seedling platforms 20u, 20m, and 20d of the preliminary seedling frame 19 of the present case, and the operator holds the fertilizer bags by switching from the deployed form to the stacked form. It may be possible to omit the work of walking in the field. Due to the structure of the spare seedling frame 19 of the present case, the above-described operation can be performed if it is about one bag of a fertilizer bag of about 20 kg.

  However, the spare seedling frame 19 of the present case is made on the assumption that a seedling mat or seedling box of about 1 to 2 kg is placed on each of the spare seedling platforms 20u, 20m, and 20d. When a manure bag having a weight of about 10 times is loaded and switching from the expanded form to the laminated form is performed, the load on the component parts of the spare seedling frame 19 is easily applied, and the work is performed using a seedling mat or seedling box. Compared to the conditions, there is a problem that the durability of the reserve seedling frame 19 is quickly lowered.

In addition, the loading area of the spare seedling platforms 20u, 20m, and 20d is adapted to the seedling mat and seedling box, and is smaller than the area of a general fertilizer bag, so the loading posture of the fertilizer bag is stabilized. However, it falls in the middle of conveyance, and the operator has to go down to the field and pick up the fertilizer bag, which increases the labor of the operator and lowers the work efficiency.
Note that there is almost no difference in the areas of the seedling mat and the seedling box under standard cultivation conditions.

  And the capacity of the storage hopper of the fertilizer application device 17 provided in the seedling transplanter of this case is about 10 kg per one piece, and only one piece of fertilizer bag can be replenished. In this case, at least three bags need to be loaded with fertilizer bags. If the worker carries the bag, there is a problem that the worker spends considerable labor. Is applied to the component parts of the reserve seedling frame 19, and there is a problem that the durability is quickly reduced accordingly.

  Furthermore, unlike a seedling mat or seedling box, there is no dedicated place for placing the fertilizer bag, so it is often placed on the floor step 11, but the seedling is transferred from the spare seedling frame 19 to the seedling planting part 16. When performing the work of replenishing the fertilizer, there is a problem that the fertilizer bag restricts the movement range of the worker and lowers the work efficiency.

A configuration that solves the above problem is shown below.
As shown in FIGS. 19 and 20, a mounting stay 101 is provided on the upper side of the base support frame 23 so as to face the inner side of the machine body, and the main support frame 24 and the sub-support frame of the preliminary seedling frame 19 are provided at the inner side of the machine body of the mounting stay 101. 25 is provided. Further, a support arm 102 is provided on the outside of the body of the mounting stay 101, and a position of the support arm 102 that is below the central portion in the left-right direction of the preliminary seedling platforms 20u, 20m, and 20d that overlap in the vertical direction in a stacked form. The 1st rotation pin 103 is provided in this. Then, the base side of the rotating arm 104 is provided above the first rotating pin 103, and the fertilizer mounting table 105 is provided on the end side of the rotating arm 104.

  As shown in FIG. 19, when the turning arm 104 is turned forward, the fertilizer placing table 105 is positioned below the preliminary seedling placing table 20u located in the front row in the unfolded form, and protrudes toward the front side of the body. At the same time, when the rotating arm 104 is rotated rearward, the fertilizer mounting table 105 is positioned below the preliminary seedling mounting table 20d located in the last row in the unfolded form, and protrudes toward the front side of the machine become. At this time, the machine body outer side end portion of the fertilizer mounting table 105 is positioned below the machine body outer end parts of the preliminary seedling mounting tables 20u, 20m, and 20d, and does not protrude excessively outside the machine body.

  Although it is not preferable that the fertilizer mounting table 105 protrudes outward from the outer side edge of the spare seedling frame 19, the fertilizer placement table 105 moves to the inner side from the inner side edge of the machine body, and the floor step 11 includes an operator. There is no problem in moving to a place where does not move.

  When moving the floor step 11, the operator basically keeps his / her foot away from the end of the floor step 11 in order to ensure the stability of the scaffold. Therefore, even if the fertilizer placing table 105 is positioned above the end of the floor step 11, it does not come into contact with the operator's feet, and the fertilizer placing table 105 is not damaged by the operator.

  By positioning the inner end portion of the fertilizer placing table 105 closer to the inner side than the inner end portion of the preliminary seedling frame 19, the operator can easily see the fertilizer placing stand 105 and work on the floor step 11. Since it approaches the operator who performs, it becomes easy for a worker to take out a fertilizer bag from the fertilizer mounting stand 105, and work efficiency improves.

  The main support frame 24 and the sub support frame 25 are provided in the vertical direction on the inner side of the rotary arm 104 so that the main support frame 24 and the sub support frame 25 are connected to the rotary arm 104. It becomes a rotation restricting member toward the inside of the machine body.

  Thereby, it is prevented that the rotating arm 104 is moved too much and the fertilizer placing table 105 is excessively moved in the inner direction of the machine body, and an operation for moving the fertilizer placing table 105 to an appropriate position becomes unnecessary. The efficiency is improved, and the fertilizer placing table 105 is brought into contact with the bonnet 13 and the like, so that the fertilizer placing table 105, the bonnet 13 and peripheral components are prevented from being damaged.

  With the above configuration, when the fertilizer bag is loaded from the end of the field, if the pivot arm 104 is rotated to the front side of the machine body, the fertilizer placing table 105 can be protruded forward of the machine body, so that the outside of the field. Workers can easily load the fertilizer on the aircraft, improving work efficiency.

  In particular, when working in a field with a water channel at the end of the field, or in a field where the scaffolding at the end of the field is unstable, the operator does not have to step out and load the fertilizer bag into the machine. The labor is reduced and the fertilizer bag is dropped, and the work of picking up the fertilizer bag becomes unnecessary, so that the work efficiency is improved.

  In addition, since the rotation arm 104 can be rotated to the outside of the machine body and the fertilizer placing table 105 can be held in a posture protruding to the outside of the machine body, the fertilizer placing table 105 can be placed at the farm field end even if the machine body is placed on the farm field side. Since it can approach, it becomes possible to respond to various work conditions, and the work efficiency can be improved and the labor of the worker can be reduced.

  When the fertilizer placement table 105 is moved, the rotation arm 104 is rotated in the outer direction of the machine body, so that the rotation arm 104 and the fertilizer placement table 105 do not move on the floor step 11. Can replenish seedlings and fertilizers on the floor step 11 without avoiding the rotating arm 104 and the fertilizer mounting table 105, and work efficiency is improved.

  Furthermore, the fertilizer can be obtained by adopting a configuration in which the outer end portion of the fertilizer mounting table 105 is positioned almost directly below the outer end portion of the preliminary seedling frame 19 regardless of whether the fertilizer mounting table 105 is moved to the front part or the rear part of the machine body. Since it is possible to prevent the mounting table 105 from protruding outside the apparatus, the fertilizer mounting table 105 is prevented from being damaged due to contact with a wall or the like, and durability is improved.

  Further, if the fertilizer placing table 105 is moved to the rear side of the machine body, the fertilizer placing table 105 can be brought close to the fertilizer application device 17, so that the operator takes the fertilizer bag from the fertilizer placing table 105 and moves it to the fertilizer application device 17. The distance is shortened, the work efficiency is improved, and the labor of the worker is reduced.

  Since the fertilizer bag can be placed on the fertilizer placing table 105 until the fertilizer replenishment operation is performed, the number of fertilizer bags placed on the floor step 11 is reduced, and the operator However, it becomes easier to move during replenishment work for seedlings and fertilizers, improving work efficiency.

Next, an adjustment mechanism of the inter-strain switching mechanism 500 that switches the number of rotations of the plurality of seedling planting devices 408 of the seedling planting unit 4 and changes the number of times of seedling planting in one straight advance will be described.
A mission case 211 that receives driving force from the engine 210 is provided, and a stock-to-stock switching gear unit (not shown) that transmits rotational driving force to the PTO shaft 2p is provided in the mission case 211. The rotation speed of the PTO shaft 2p is changed by changing the combination of the gears of the inter-gear gear unit, and the rotation speed of the lead cam mechanism 404 and the planting transmission shaft 407 operated via the planting drive case 406 is changed. The left and right sliding speed of the seedling tank 401 and the rotating pace of the seedling planting device 408 are switched to change between so-called stocks before and after the seedling.

In addition, although it is set as 37, 42 ... 70, and 80 as description between stocks, this shows the number of the seedlings planted in the straight section of 1 tsubos.
As shown in FIGS. 37 and 38, the inter-stock switching mechanism 500 is provided with a stock switching arm 501 that switches the gear of the inter-gear gear unit on the front side of the driver seat 12 of the traveling vehicle body 2 and below the floor step 11. The inter-stock switching arm 501 is provided with an inter-stock switching lever 502 that allows an operator to perform an inter-stock switching operation. The inter-stock switching lever 502 is slid downward when not in use, and is housed in a cover sheet (not shown) provided on the floor step 11, and the cover sheet is lifted up during use. Is slid upward to make it ready for use.

The inter-stock switching arm 501 is configured to be slidable in the left-right direction of the machine body along the rotation axis at a place other than the rotation end in the front-rear direction.
Then, one end of a support stay 503 is provided on the rotation shaft of the inter-stock switching arm 501, the other end of the support stay 503 is fixed to the support frame 504 on the rear side of the machine body, and the inter-stock switching arm 501 is rotated. The support stay 503 does not rotate even if it is moved. Further, the support stay 503 is provided with an inter-stock sensor 505 for determining the current inter-stock. In addition, the inter-stock switching arm 501 is formed with first and third upper protrusions 506a1 and 506a2 that protrude upward from the body in a side view, and a lower protrusion 506b that protrudes downward from the body. A detection plate 506 is attached.

The inter-stock sensor 505 has a simple configuration when it is configured as a switch type that is turned on when contacting the first and second upper projections 506a1 and 506b2.
The stock switching arm 501 is rotated to the front side of the machine body via the stock switching lever 502, the stock gear unit is switched to 37 plants at the position where the stock sensor 505 contacts the first upper projection 506a1, and the second upper projection The inter-gear gear unit is switched to 42 planting at a position in contact with the portion 506a2. The 37 planting and the 42 planting are so-called “sparse planting”. Then, at the position where the inter-strain sensor 505 contacts the lower convex portion 506b, the inter-strain gear unit is switched to a so-called “standard” of 50 to 80 plantings.

  Switching from 50 shares to 80 shares described above can be performed by changing the left-right position of the fuselage switching arm 501 when the stock sensor 505 is above the lower convex portion 506b. It shall be switched to 80 shares. At this time, since the inter-strain sensor 505 does not contact the detection plate 506, the inter-strain sensor 505 and the detection plate 506 do not contact each other even if the inter-strain switching operation is performed, and thus durability is maintained.

In the detection plate 506, notches 506s are formed on the right side of the lower convex portion 506b.
Then, when the stock sensor 505 is turned on by contacting the first upper convex portion 506a1 or the second upper convex portion 506a2, the restraint control is performed so that the traveling speed of the traveling vehicle body 2 does not increase beyond the set speed. When the speed is higher than the speed, the traveling output is forcibly reduced to decelerate.

  With the above configuration, when the stock sensor 505 comes into contact with the first upper convex portion 506a1 or the second upper convex portion 506a2 at the front and rear ends of the detection plate 506, the traveling speed of the traveling vehicle body 2 is suppressed to the set speed. It is possible to prevent the seedling planting device 408 ... from rotating poorly and disturbing the seedling planting interval or temporarily interrupting the planting of seedlings by performing excessively high speed traveling during sparse planting work. The planting accuracy of seedlings at the time of planting is improved.

By improving the planting accuracy at the time of sparse planting, it is possible to prevent seedlings larger than the set planting number from being planted in the field, so that the consumption of seedlings is prevented from increasing.
In addition, by forming the notch 506s on the right side of the lower convex portion 506b, foreign matter such as earth and sand can be dropped from the notch 506s, so that the inter-strain sensor 505 is erroneously detected during normal planting work. Therefore, the traveling speed is not restricted, and it is possible to work at high speed during normal planting, and the work efficiency is improved.

16 Seedling planting part 17 Fertilizer 19 Preliminary seedling frame 101 Mounting stay (mounting member)
102 Support arm (support member)
103 1st rotation pin (1st fulcrum member)
104 Rotating arm (Rotating member)
105 Fertilizer mounting table (fertilizer mounting member)
106 2nd rotation pin (2nd fulcrum member)
109 Third pivot pin (third fulcrum member)
114 Boss (Cylinder member)
114a Concave 115 Lock projection (regulation projection)
117 Push-up spring (push-up member)
118 Lowering switch (lowering detection member)
200 Drawing marker (drawing member)
201 Marker switching motor (switching actuator)

Claims (8)

  A seedling placing member (51) for loading seedlings on the farm field is provided on the traveling vehicle body (2) so as to be movable up and down, a support member (403) is provided at a lower portion of the seedling placing member (51), and the support member (403) is provided with a farm field. A plurality of planting devices for supplying driving force to a leveling device (5) for leveling the surface, a driving case (406) for receiving driving force from the traveling vehicle body (2), and a plurality of seedling planting devices (408) for planting seedlings Attached transmission case (405C, 405L, 405R) is provided, and a driving force is supplied to the plurality of planted transmission cases (405C, 405L, 405R) by a planted transmission shaft (407) provided in the drive case (406). A seedling transplanter characterized by that.   The plurality of planting transmission cases (405C, 405L, 405R) are filled with a lubricant, and the plurality of planting transmission cases (405C, 405L, 405R) rotate with the driving rotation of the planting transmission member (407). A planting drive rotating body (410), a planting driven rotating body (411) rotating from the planting driving rotating body (410) via a planting transmission endless belt (412), and the planting driven rotating body ( 411) is provided with a planting rotation shaft (409) for rotating a plurality of seedling planting devices (408), and the planting rotation shaft (409) is disposed below the planting transmission shaft (407). The seedling transplanter according to claim 1, wherein the seedling transplanter is characterized by the following.   Among the plurality of planting transmission cases (405C, 405L, 405R), the vertical width on the side where the planted driven rotator (411) is provided is wider than the vertical width on the side where the planting drive rotator (410) is provided. The seedling transplanter according to claim 2, wherein the seedling transplanter is formed and has a diameter larger than that of the planting drive rotor (410).   A left-right moving device (404) for moving the seedling placing member (51) in the left-right direction of the machine body is mounted on the drive case (406), and the drive force received from the traveling vehicle body (2) is placed in the drive case (406). Is provided with a transmission mechanism (406a, 406b, 406c, 406d) that transmits the left and right moving devices (404) and the planting transmission shaft (407), and the drive case (406) includes the left case (406L) and the right case (406R). The seedling transplanting machine according to any one of claims 1 to 3, wherein one of the left case (406L) and the right case (406R) is detachably provided from the other. .   The planting transmission shaft (407) is provided with a clutch mechanism (416) for interrupting transmission of driving force when the plurality of planting transmission cases (405C, 405L, 405R) are overloaded. The seedling transplanter according to any one of claims 1 to 4.   The leveling device (5) is provided between the left and right sides of the lateral leveling members (51, 51) provided at the left and right ends of the traveling vehicle body (2) and the left and right sides of the side leveling members (51, 51). A center leveling member (50) and a leveling transmission case (52, 52) for connecting the center leveling member (50) and the side leveling members (51, 51) and transmitting a driving force are provided. A leveling device (62) for moving the leveling device (5) up and down at the section (4), and a horizontal maintenance mechanism (63) for maintaining the horizontal posture of the traveling vehicle body (2) of the leveling device (5) horizontally The seedling transplanting machine according to any one of claims 1 to 5, wherein a seedling transplanting machine is provided.   The leveling lift device (62) includes a lift drive actuator (65), a lift drive member (64) rotated by the lift drive actuator (65), and the lift drive member (64) in the seedling planting part (4). ), And the horizontal maintenance mechanism (63) includes a horizontal maintenance member (69) provided on the front side of the leveling lifting member (66) and the leveling transmission case (52). The seedling transplanting machine according to claim 6, wherein the seedling transplanting machine is configured by a posture holding member (71) that protrudes rearward from the horizontal maintenance member (63).   An anti-scattering member (85) for preventing mud from scattering is provided on the upper part of the central leveling member (50), and the anti-scattering member (85) is provided on the left and right sides of the central leveling member (50) (86, 86) and a protective body (87) for connecting the front side of the support (86, 86), and the upper and rear sides of the central leveling member (50) are opened. The seedling transplanter described in 1.

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