JP3163416U - Rice transplanter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a rice transplanter that can be miniaturized. SOLUTION: A traveling machine body 4 having wheels 26, a seedling planting device 28 for planting seedlings in a farm scene provided on the traveling machine body 4, and excavation means 12 provided in front of the seedling planting device 28 are provided. . The excavation means 12 has an excavation claw 44 extending toward a farm scene, and the excavation claw 44 is configured to be rotatable about its axis. When the excavation claw 44 rotates and cuts into the field scene, a planting groove is formed in the field scene. [Selection] Figure 1

Description

  The present invention relates to a rice transplanter used to plant seedlings in a farm scene.

  For example, a rice transplanter as described in Patent Document 1 is used for non-plowing work in which seedlings are planted in a farm field that is not cultivated. This kind of rice transplanter is equipped with a traveling machine body having wheels, a seedling planting device for planting seedlings in a farm scene, and excavation supported rotatably in front of the seedling planting device. A blade and a drive mechanism for rotationally driving the excavation blade. The excavation blade is configured in a disc shape, and a blade portion is formed on the outer peripheral portion thereof. The rotating shaft of the excavating blade extends in a substantially horizontal direction, and thereby the excavating blade is rotated in the vertical direction.

  When the traveling machine moves on the field scene, the excavating blade rotates and cuts into the field scene, thereby forming a planting groove in the field scene. A seedling is planted in the planting groove by a seedling planting apparatus.

JP-A-6-153620

  In the conventional rice transplanter as described above, the following problems arise in relation to the excavation blade being rotated in the vertical direction. In order to sufficiently cut the excavating blade into the field, it is necessary to ensure a large diameter of the excavating blade. However, when the diameter of the excavating blade is increased in this way, the whole rice transplanter is increased in size, and the rice transplanter cannot be easily transported.

  Further, when the diameter of the excavating blade is increased as described above, the resistance acting on the excavating blade is increased when the excavating blade is cut into the field scene while rotating. For this reason, the driving force of a driving mechanism (for example, an engine or the like) for driving the excavating blade to rotate must be increased, which increases the size of the driving mechanism and further increases the size of the rice transplanter.

  An object of the present invention is to provide a rice transplanter that can be miniaturized.

In the rice transplanter according to claim 1 of the present invention, a traveling machine body having wheels, a seedling planting device provided on the traveling machine body for planting seedlings in a farm scene, and provided in front of the seedling planting device The excavating means has excavation claws extending toward a farm scene, and the excavation claws are configured to be rotatable about the axis thereof,
When the excavation claw rotates and cuts into the field scene, a planting groove is formed in the field scene, and a seedling is planted in the planting groove by the seedling planting device.

  Moreover, in the rice transplanter according to claim 2 of the present invention, the excavation claw extends obliquely backward with respect to the vertical direction.

  Moreover, in the rice transplanter according to claim 3 of the present invention, a tip portion of the excavation claw is formed in a substantially inverted triangle shape, and a top portion thereof faces the farm scene side.

  Moreover, in the rice transplanter according to claim 4 of the present invention, the excavation claw is arranged between the wheel and the seedling planting device.

  According to the rice transplanter according to claim 1 of the present invention, the excavation claw extends toward the field scene and rotates around its axis, so that the size of the excavation means is made compact. Can do. Therefore, the whole rice transplanter can be reduced in size, and the rice transplanter can be easily transported. In addition, since the resistance acting on the excavation claw is reduced when the excavation claw rotates and cuts into the field scene, the driving force of a drive mechanism (for example, an engine or the like) for driving the excavation claw to rotate can be kept small. . Thereby, the magnitude | size of a drive mechanism can be restrained small and the whole rice transplanter can be further reduced in size.

  Further, according to the rice transplanter according to claim 2 of the present invention, since the excavation claw extends obliquely backward with respect to the vertical direction, when weeds etc. growing on the farm field are entangled with the excavation claw In addition, entangled weeds and the like easily fall out backward from the excavation claw. Thereby, the excavation claw can be stably rotated without being obstructed by weeds or the like.

  Moreover, according to the rice transplanter of Claim 3 of this invention, since the front-end | tip part of an excavation nail | claw is comprised by the substantially inverted triangle shape, and the top part has faced the field scene side, weeds etc. which are growing on the field Slid down below the tip of the excavation claw without being entangled with the tip of the excavation claw. Thereby, it can suppress that weeds etc. get entangled with the front-end | tip part of an excavation nail | claw.

  Further, according to the rice transplanter according to claim 4 of the present invention, since the excavation claw is disposed between the wheel and the seedling planting device, the traveling machine body is supported by the wheel in front of the excavation claw. As a result, the stability of the excavating claw during rotation can be improved.

It is a side view which shows the rice transplanter by one Embodiment of this invention. It is a perspective view which extracts and shows the engine of FIG. 1, a gear case, and a pair of excavation nail | claw. It is sectional drawing which shows the internal structure of a gear case. (A) is sectional drawing which shows the state by which a pair of planting grooves were formed in the field scene by a pair of excavation nail, (b) is a seedling planting in a pair of planting grooves formed in the field scene It is sectional drawing which shows the state performed.

  Hereinafter, an embodiment of a rice transplanter according to the present invention will be described with reference to the accompanying drawings. FIG. 1 is a side view showing a rice transplanter according to an embodiment of the present invention, FIG. 2 is a perspective view showing the engine, the gear case, and a pair of excavation claws extracted from FIG. 1, and FIG. FIG. 4A is a cross-sectional view showing an internal structure, FIG. 4A is a cross-sectional view showing a state in which a pair of planting grooves is formed in a farm scene by a pair of excavating claws, and FIG. It is sectional drawing which shows the state by which the seedling was planted by a pair of planting groove | channel formed in.

  With reference to FIG. 1, the rice transplanter 2 of this embodiment is comprised from the walk type rice transplanter. The rice transplanter 2 includes a traveling machine body 4. The traveling machine body 4 includes a main frame 6 extending in the front-rear direction, a planting part frame 8 connected to a rear portion of the main frame 6, and the main frame 6 and the planting part. And a pair of wheels 26 (described later) that movably support the frame 8. A power unit 10 is supported on the front portion of the main frame 6, and an excavation unit 12 (which constitutes excavation means) is supported on the rear portion. A planting part 14 is supported on the planting part frame 8. A drive transmission shaft (not shown) is rotatably arranged inside the main frame 6, and a drive transmission mechanism (not shown) is arranged inside the planting part frame 8. The drive transmission shaft of the main frame 6 and the drive transmission mechanism of the planting part frame 8 are drive-coupled to each other.

  The power unit 10 includes an engine 16, a fuel tank 18, and a transmission case 20, and the upper part thereof is covered with a bonnet 22. The fuel tank 18 stores fuel to be supplied to the engine 16. The engine 16 is drivingly connected to the transmission case 20 in the transmission case 20 and the main frame 6. The front end of the chain case 24 is rotatably connected to both sides of the transmission case 20. The pair of chain cases 24 extend rearward, and wheels 26 are rotatably supported at the rear ends of the chain cases 24. The driving force from the engine 16 is transmitted to the pair of wheels 26 via the transmission case 20 and the pair of chain cases 24, whereby the pair of wheels 26 are rotated in a predetermined direction, whereby the traveling machine body 4 is moved forward (see FIG. 1 in the left direction).

  The planting unit 14 includes a seedling planting device 28, and the seedling planting device 28 includes a seedling mounting table 30 and a planting claw 32. The seedling stage 30 extends slightly inclined rearward from the rear part of the planting part frame 8, and a seedling mat (not shown) is placed on the seedling stage 30. The seedling stage 30 is drivingly connected to the drive transmission mechanism of the planting part frame 8. The driving force from the engine 16 is transmitted to the seedling stage 30 through the transmission case 20, the drive transmission shaft of the main frame 6 and the drive transmission mechanism of the planting part frame 8, so that the seedling stage 30 is moved in the horizontal direction ( In FIG. 1, it is reciprocated in the direction perpendicular to the paper surface. The planting claws 32 are drivingly connected to the drive transmission mechanism of the planting part frame 8. The driving force from the engine 16 is transmitted to the planting claw 32 via the transmission case 20, the drive transmission shaft of the main frame 6 and the drive transmission mechanism of the planting part frame 8, so that the planting claw 32 is elliptical vertically. It is swung to draw a trajectory. As the planting claws 32 are swung in this manner, the planting claws 32 divide and take out a single seedling 34 (see FIG. 4) from the seedling mat placed on the seedling mounting table 30, It comes to be planted in the field scene 36. In the present embodiment, the seedling planting device 28 is configured for two-row planting.

  A pair of operation handles 38 for operating the rice transplanter 2 as required are supported at the rear of the planting part frame 8. The pair of operation handles 38 extend obliquely rearward along the seedling mount 30. The planting part frame 8 supports a pair of floats 40 for leveling the farm scene 36, and the pair of floats 40 is disposed below the traveling machine body 4 with a gap.

  As shown in FIG. 2, the excavation unit 12 includes an engine 42, a pair of excavation claws 44, and a gear case 46 for transmitting a driving force from the engine 42 to the pair of excavation claws 44. The excavation unit 12 is disposed in front of the seedling planting device 28.

  The excavation claw 44 is detachably inserted and supported at the lower end portion of the support cylinder portion 48 extending downward from the gear case 46, and is disposed between the wheel 26 and the seedling planting device 28. Furthermore, the excavation claw 44 extends toward the farm scene 36 and extends at an angle θ (for example, about 30 to 40 °) rearward (rightward in FIG. 1) with respect to the vertical direction. The tip portion 50 of the excavation claw 44 is formed in a substantially inverted triangular shape and a plate shape, and its top portion faces the farm scene 36 side. The tip 50 of the excavation claw 44 protrudes below the float 40 through an insertion hole 52 provided in the rear part of the float 40, and the protruding length L is, for example, about 5 to 7 cm.

  As shown in FIG. 3, the gear case 46 is supported by the main frame 6, and a drive gear 54 and a pair of driven gears 56 are rotatably supported therein. The driving gear 54 is drivingly connected to a driving shaft 58 of the engine 42, and the pair of driven gears 56 are drivingly connected to an upper end portion of a support cylinder portion 48 into which the excavation claw 44 is inserted and supported. The drive gear 54 is disposed between a pair of driven gears 56, and a drive chain 60 is movably wound around the drive gear 54 and the pair of driven gears 56. One side of the drive chain 60 extends in a substantially V shape between the pair of driven gears 56 and meshes with the drive gear 54, and the other side extends linearly between the pair of driven gears 56 and is separated from the drive gear 54. . A support plate 62 is supported on the upper surface of the gear case 46, and a support column 64 is provided on the support plate 62 so as to extend upward. A controller 66 for adjusting the rotational speed of the engine 42 is attached to the upper end portion of the support column 64, and this controller 66 is electrically connected to the engine 42 via a cable 68.

  When the engine 42 is driven, the driving gear 54 is rotated in a predetermined direction (direction indicated by an arrow P in FIG. 3) by the driving force, and the rotation is transmitted to the pair of driven gears 56 via the driving chain 60. Is done. Accordingly, the pair of driven gears 56 are rotated in synchronization with predetermined directions (directions indicated by arrows Q and R in FIG. 3), and accordingly, the pair of excavation claws 44 are respectively predetermined about the respective axes. It is rotated in synchronization with the direction (directions indicated by arrows S and T in FIG. 2). In addition, the rotation speed of the excavation claw 44 can be adjusted by operating the controller 66, and can be set to a predetermined rotation speed within a rotation speed range of 800 to 1200 rpm, for example.

  Next, with reference also to FIG. 4, the no-tillage work using the rice transplanter 2 of this embodiment is demonstrated. The rice transplanter 2 is loaded on the uncultivated field scene 36 where rice plants remain, and the seedling mat is placed on the seedling stand 30 and the engines 16 and 42 are started. When the traveling machine body 4 is moved forward while holding the pair of operation handles 38 with both hands, the farm scene 36 (that is, the portion of the farm scene 36 where no rice plant is planted) is leveled by the pair of floats 40. At the same time, the tip portions 50 of the pair of excavating claws 44 are cut into the field scene 36 that is leveled while rotating. Thereby, the farm scene 36 is excavated into a groove shape, and a pair of planting grooves 70 are formed in the farm scene 36, and the pair of planting grooves 70 has a width necessary for planting the seedlings 34 and the machine body 4. It extends in the traveling direction (see FIG. 4A). A seedling 34 is planted by the seedling planting device 28 in each of the pair of planting grooves 70 formed in this way (see FIG. 4B).

  In the rice transplanter 2 of the present embodiment, the excavation claw 44 extends toward the farm scene 36 and rotates around its axis, so that the size of the excavation means 12 can be kept compact, and the rice transplanter 2 The overall size can be kept compact. In addition, since the resistance acting on the excavation claw 44 is reduced when the excavation claw 44 rotates while cutting into the farm scene 36, the driving force of the engine 42 for driving the excavation claw 44 to rotate can be kept small. The size of the whole rice transplanter 2 can be further reduced.

  Further, the tip 50 of the excavation claw 44 is formed in a substantially inverted triangle shape, and the top of the excavation claw 44 faces the field scene 36, so that weeds and the like growing on the field scene 36 are located at the tip 50 of the excavation claw 44. Without entanglement, it slides down below the tip 50 of the excavation claw 44. Thereby, weeds and the like can be prevented from being entangled with the tip 50 of the excavation claw 44. Even when weeds or the like are entangled with the excavation claw 44, the excavation claw 44 is inclined backward with respect to the vertical direction, so that the entangled weeds and the like easily fall out from the excavation claw 44. Thereby, the excavation claw 44 can be stably rotated without being disturbed by weeds or the like.

  As mentioned above, although one Embodiment of the rice transplanter according to this invention was described, this invention is not limited to this embodiment, A various deformation | transformation thru | or correction | amendment are possible, without deviating from the scope of this invention.

  In the said embodiment, although the seedling planting apparatus 28 was comprised from the thing for 2 row planting, you may comprise from the thing for 3 row planting, 4 row planting, or 5 row planting or more.

  Moreover, although the said embodiment demonstrated the case where the rice transplanter 2 was used for a non-plowing work, in a plowing work (namely, the work which transplants a seedling to the field scene plowed and watered and plowed). It can also be used. Moreover, in the said embodiment, although the rice transplanter 2 was comprised from the walk type rice transplanter, it can also be comprised from a riding type rice transplanter.

  Moreover, in the said embodiment, although the protrusion length L of the front-end | tip part 50 of the excavation nail 44 was fixed, you may make it provide the protrusion length adjustment mechanism for adjusting this protrusion length L. FIG.

2 Rice transplanter 4 Traveling machine 12 Excavation part (excavation means)
26 Wheel 28 Seedling planting device 34 Seedling 36 Farm scene 42 Engine 44 Drilling claw 46 Gear case 50 Tip 70 Planting groove

Claims (4)

A traveling machine body having a wheel; a seedling planting device provided on the traveling machine body for planting seedlings in a farm scene; and a drilling unit provided in front of the seedling planting device; , Having a drilling claw extending toward the farm scene, the drilling claw is configured to be rotatable about its axis,
A rice transplanter characterized in that a planting groove is formed in a farm scene by cutting the farming claw into the farm scene while rotating, and seedlings are planted in the planting groove by the seedling planting device.   2. The rice transplanter according to claim 1, wherein the excavation claws extend obliquely backward with respect to a vertical direction.   The rice transplanter according to claim 1 or 2, wherein a tip portion of the excavation claw is formed in a substantially inverted triangular shape, and a top portion thereof faces the field scene side. The said excavation nail | claw is arrange | positioned between the said wheel and the said seedling planting apparatus, The rice transplanter in any one of Claims 1-3 characterized by the above-mentioned.

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