JP4396103B2 - Seedling planting equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention belongs to the technical field of a seedling planting device that is transferred to a field scene and planted in a state where the seedling is held by a seedling planting tool.
[0002]
[Prior art]
Conventionally, in a seedling transplanting machine such as a rice transplanter, a final gear is provided at a position deviated from the rotation center of a rotating case that rotates integrally with the driving shaft by driving rotation of a left and right driving shaft protruding from the transmission case, A seedling planting apparatus having a configuration in which a seedling planting tool is provided so as to rotate the final gear in the opposite direction with respect to the rotation case and rotate integrally with the final gear is provided. This seedling planting device moves the seedling planting tool up and down by revolving the rotating case, and scrapes and holds one seedling from a mat-like seedling on the seedling mounting table by the seedling planting tool. The plant is transferred to the farm scene and seedlings are planted in the farm field. In the rotating case, the intermediate gear fixed so as not to rotate to the airframe side is transmitted to the final gear via the counter gear, and the shafts of the intermediate gear, counter gear and final gear are viewed from the side. The hearts are in line with each other.
[0003]
And the seedling planting apparatus has a configuration in which a rotating body is provided for each planting strip, and a seedling planting tool is attached only to the left and right sides of the rotating body (see, for example, Patent Document 1).
[0004]
[Patent Document 1]
Japanese Patent Laid-Open No. 2001-269023
[Problems to be solved by the invention]
In the conventional seedling planting device, a rotating case is provided for each planting line. Therefore, in a multi-planted seedling transplanting machine, the number of rotating cases increases, and the number of rotating cases is attached. The number of parts including gears such as the intermediate gear, the counter gear, and the final gear increases, resulting in an increase in weight and an increase in cost.
[0006]
In addition, a transmission shaft that rotates integrally with the final gear is extended to the left and right sides of the rotating case, and a plurality of seedling planting tools are attached to the transmission shaft and arranged side by side. It is conceivable to operate the tool, but as long as the transmission shaft extends to the left and right as long as it extends between the planting strips, the operation of the seedling planting tool becomes unstable and the transmission shaft does not interfere with surrounding structures. Therefore, there is a possibility that the degree of freedom of design such as the arrangement of other structures is reduced, and the cost is increased.
[0007]
Further, in this seedling planting device, the shafts of the intermediate gear, the counter gear, and the final gear are positioned in a straight line with each other in a side view, so that the rotation transmission accuracy to the final gear by the gear in the rotating case can be improved. Considering the reduction of the backlash of the final gear due to the backlash, it is necessary to some extent between the shafts of the transmission gears. Therefore, the rotation case becomes longer in the direction of the arrangement of the shaft centers, and there is a limit to the miniaturization of the rotation case.
[0008]
[Means for Solving the Problems]
In order to solve the above problems, the present invention has taken the following technical means.
That is, according to the first aspect of the present invention, the final gear (73) revolving by the rotation of the rotating body (31) rotating about the axis in the left-right direction rotates in the direction opposite to the rotating direction of the rotating body (31). together is, the in seedling planting apparatus provided NaeUe with tool (32) to rotate integrally with the final gear (73), the teeth of the fixed gear among fixed to the machine body side so as not to rotate against the machine body A rotating gear (67) meshing with (65) is provided on the rotating body (31), and the rotating gear (67) rotates while revolving as the rotating body (31) rotates. The seedling planting apparatus is characterized in that it is configured to transmit to the gear (73).
[0009]
Accordingly, in the seedling planting device according to claim 1, the rotation gear (67) that meshes with the fixed gear (65) rotates by revolving around the axis of the rotating body (31) in the left-right direction, The final gear (73) is transmitted from the rotating gear (67) and rotated in the opposite direction to the rotating direction of the rotating body (31), and the seedling planting tool (32) corresponds to the rotating position of the rotating body (31). ) Is controlled, and seedlings are planted in the field by the seedling planting tool (32). The shaft center (68) of the rotating gear (67) can be displaced from the center of rotation of the rotating body (31), and the rotating body (31) can be reduced in size and transmitted between the shafts of the gears. Thus, it is possible to improve the rotation transmission accuracy to the final gear (73) and reduce the backlash of the final gear (73) due to the backlash of the gear.
[0010]
In the invention according to claim 2, the rotation transmission ratio from the fixed gear (65) to the rotation gear (67) and the rotation transmission ratio from the rotation gear (67) to the final gear (73) are set to reciprocal numbers. The seedling planting apparatus according to claim 1, wherein the seedling planting apparatus is provided.
[0011]
Therefore, the seedling planting device according to claim 2 has a rotational transmission ratio from the fixed gear (65) to the rotation gear (67) and the rotation gear (in addition to the operation of the seedling planting device according to claim 1). 67) to the final gear (73) are set to the reciprocal numbers, the final gear (73) rotates once in the reverse direction for each rotation of the rotating body (31). The posture of the seedling planting tool (32) is controlled corresponding to the rotational position of (31).
[0012]
In the invention according to claim 3, the seedling planting tool (32) is attached to the left and right of the rotating body (31), and the input unit (60, 61) for inputting rotational power to the rotating body (31) is provided in the left-right direction. The seedling planting apparatus according to claim 1, wherein the seedling planting apparatus is located between the left and right seedling planting tools (32).
[0013]
Therefore, the seedling planting device according to claim 3 is a rotating body that rotates in addition to the operation of the seedling planting device according to claim 1 or 2 by rotating around the axial center of the rotating body (31). The seedling planting tool (32) attached to the left and right of (31) is used to plant seedlings in a plurality of strips in the field. At this time, even if the right and left seedling planting tools (32) are provided and the rotational load of the rotating body (31) increases, the input units (60, 61) for inputting rotational power to the rotating body (31) are left and right. In the middle of the left and right seedling planting tool (32), the rotating body (31) can be smoothly rotated.
[0014]
According to a fourth aspect of the present invention, the intermediate gear (69) provided on the rotating body (31) is transmitted from the intermediate gear (69) to the final gear (73) via the counter gear (70, 72). The shaft center (68 ) of (69), the shaft center (71 ) of the counter gear (70, 72) and the shaft center ( 36 ) of the final gear (73) are not located in a straight line with each other. A seedling planting apparatus according to any one of claims 1 to 3.
[0015]
Therefore, the seedling planting device according to claim 4 is provided by rotating the rotating body (31) around the axis in the left-right direction in addition to the operation of the seedling planting device according to any one of claims 1 to 3. Then, the intermediate gear (69) is transmitted through the counter gear (70, 72), and the final gear (73) is rotated in the direction opposite to the rotational direction of the rotating body (31), so that the seedling planting tool (32) To control the attitude. In addition, the shaft center (68) of the intermediate gear (69) , the shaft center (71) of the counter gear (70, 72) , and the shaft center ( 36 ) of the final gear (73) are not positioned in a straight line when viewed from the side. Therefore, while reducing the size of the rotating body (31), it is possible to widen the distance between the shafts of the transmission gears, improving the accuracy of rotation transmission to the final gear (73) and the final gear by backlash of the gear. (73) can be reduced.
[0016]
Further, the invention according to claim 5 is characterized in that the rotary gear (67) and the final gear (73) are arranged to the left and right with respect to the input portion (60, 61). A seedling planting device was used.
[0017]
Therefore, in addition to the operation of the seedling planting device according to claim 3, the seedling planting device according to claim 5 has an input unit (60, 61) for inputting rotational power to the rotating body (31). Since the rotating gear (67) and the final gear (73) are arranged separately on the left and right, the right and left weight balance of the rotating body (31) with respect to the input unit (60, 61) and the left and right seedling planting tool (32) The weight balance of the right and left of the whole seedling planting apparatus including can be made uniform, and the rotating body (31) can be smoothly rotated.
[0018]
Further, the invention according to claim 6 is provided with a backlash stopping mechanism (40) for absorbing backlash of the final gear (73) due to the backlash of the gear, and the backlash stopping mechanism (40) with respect to the input portion (60, 61). The seedling planting device according to claim 3 or 5, characterized in that the final gear (73) is arranged in a left-right manner.
[0019]
Therefore, the seedling planting device according to claim 6 has a backlash of the final gear (73) due to the backlash of the gear by the backlash stopping mechanism (40) in addition to the operation of the seedling planting device according to claim 3 or 5. And the posture of the seedling planting tool (32) is accurately controlled appropriately. And since the ratchet mechanism (40) and the final gear (73) are arranged to the left and right with respect to the input part (60, 61), the left and right of the rotating body (31) with respect to the input part (60, 61) are arranged. As a result, the right and left weight balance of the entire seedling planting apparatus including the left and right seedling planting tools (32) can be made uniform, and the rotating body (31) can be smoothly rotated.
[0020]
【The invention's effect】
According to the seedling planting device according to claim 1 and 2, it is possible to improve the rotation transmission accuracy to the final gear (73) and to reduce the play of the final gear (73) due to the backlash of the gear. An appropriate seedling can be planted with the tool (32), and the rotating body (31) can be reduced in size, so that the rotational load on the rotating body (31) can be reduced, the weight thereof can be reduced, and the cost can be reduced.
[0021]
Moreover, according to the seedling planting apparatus of Claim 3, in addition to the effect of the seedling planting apparatus of Claim 1 or 2, the seedling planting tool (32) attached to the right and left of the rotary body (31) As a result, seedlings can be planted in a plurality of strips in the field, reducing the number of parts and reducing the weight and cost. Moreover, a rotary body (31) can be rotated smoothly and a seedling can be planted appropriately in multiple strips.
[0022]
Moreover, according to the seedling planting apparatus of Claim 4, in addition to the effect of the seedling planting apparatus of any one of Claims 1 thru | or 3, the improvement of the rotational transmission accuracy to the last gear (73), and a gear The backlash of the final gear (73) can be reduced, an appropriate seedling can be planted by the seedling planting tool (32), and the rotating body (31) can be reduced in size. 31) Reduction of rotational load, weight reduction, and cost reduction can be achieved.
[0023]
Moreover, according to the seedling planting apparatus of Claim 5, in addition to the effect of the seedling planting apparatus of Claim 3, a rotary body (31) can be rotated smoothly and seedling planting appropriately. Can be attached.
[0024]
Moreover, according to the seedling planting apparatus of Claim 6, in addition to the effect of the seedling planting apparatus of Claim 3 or 5, a rotary body (31) can be rotated smoothly and seedlings can be appropriately formed. Can be planted.
[0025]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of the present invention will be described with reference to the drawings.
1 and 2 show a riding-type rice transplanter 1, and this riding-type rice transplanter 1 is composed of a traveling vehicle body 2 and a six-row planting part 3.
[0026]
An engine 4 as a drive source is provided at the approximate center of the traveling vehicle body 2, and the front wheels 6, 6 and the rear wheels 7, 7 are driven by the driving of the engine 4 through the traveling mission case 5. The traveling vehicle body 2 travels by driving the wheels 6, 6, 7, 7. A cockpit 8 is provided above the engine 4, and a steering handle 9 is provided on the front side of the cockpit 8. An elevating link mechanism 10 is provided at the rear part of the traveling vehicle body 2, and the seedling planting part 3 is mounted via the elevating link mechanism 10, and is provided so as to be moved up and down by expansion and contraction of the hydraulic elevating cylinder 11. . The power from the traveling vehicle body side is transmitted to the seedling planting portion 3 through the planting clutch case 12.
[0027]
Further, an inter-stock shift lever 13 that is operated stepwise is provided at the step portion in front of the cockpit, so that the operating speed of the seedling planting section 3 with respect to the traveling speed of the traveling vehicle body 2 can be changed. With this inter-strain shift lever 13, the planting operator can set the planting strains of seedlings to be transplanted in the field. Therefore, unless the inter-strain shift lever 13 is operated, the seedling planting unit 3 is operated at a speed proportional to the traveling speed.
[0028]
The seedling planting unit 3 includes a seedling placing table 20, a planting transmission unit 21, and seedling planting devices 22,. At the lower part of the seedling planting part 3, a center float 23 and side floats 24, 24 are provided on both sides, and the floats 23, 24, 24 are configured to slide in a field scene. .
[0029]
In addition, the seedling planting unit 3 operates the seedling planting device 22 by the power from the planting transmission unit 21. The seedling mounting table 20 is supported by a seedling mounting table support rollers 25 and 25 at the upper part and a left and right movement guide plate 26 at the lower part so as to be movable left and right. Then, the seedling planting unit 3 moves the seedling mounting table left and right moving rod 27 to which the seedling mounting table 20 is fixed by the power from the planting transmission unit 21 to move left and right to move the seedling mounting table 20 left and right. The seedlings are scraped one by one by the seedling planting device 22. The left and right moving guide plate 26 is provided with seedling scraping openings 26a of the seedling planting devices 22,. The seedling mounting table 20 has a known configuration in which mat-shaped seedlings are sequentially transferred to the seedling planting device side along the seedling mounting table 20 by the seedling feeding belts 28,.
[0030]
The seedling planting device 22 is operated by driving a seedling planting device drive shaft 30 that rotates at a constant speed in proportion to the traveling speed of the airframe at the rear end portion of the planting transmission frame 29 of the planting transmission unit 21. It is supposed to be. The seedling planting device drive shaft 30 is driven and driven via a driven sprocket 38 and a safety clutch 39 which are driven by transmission from a chain 37 wound from the front side. The safety clutch 39 includes a drive clutch pawl 39a integrally provided at an end of the driven sprocket 38, a passive clutch pawl body 39b including a passive clutch pawl meshing with the drive clutch pawl 39a, and the driven sprocket 38. A compression spring 39c that urges the body 39b is provided. The driven sprocket 38, that is, the drive clutch pawl 39a is provided so as to rotate around the seedling planting device drive shaft 30, and the passive clutch pawl body 39b rotates integrally with the seedling planting device drive shaft 30. It has become. The claw portions of the drive clutch 39a claw and the passive clutch claw body 39b are provided with inclined surfaces, and when the seedling planting device 22 interferes with a foreign object or the like to cause a mechanical lock, the inclined surfaces resist the compression spring 39c. The drive clutch pawl 39a, that is, the driven sprocket 38 moves to the side opposite to the passive clutch pawl body 39b, and the transmission of the safety clutch 39 is cut off.
[0031]
An input gear 60 that rotates integrally with the passive clutch pawl 39 b is provided and transmitted to the drive gear 61 that meshes with the rear side of the input gear 60, and the rotation case 31 of the seedling planting device 22 is driven by the drive gear 61. And is configured to rotate integrally. The drive gear 61 is provided at a substantially central position between the rotating case 31 and the left and right seedling planting tools 32 attached to the rotating case 31 in the left-right direction. Note that the input gear 60 or the drive gear 61 serves as an input unit for inputting rotational power to the rotary case 31.
[0032]
The seedling planting device 22 includes a rotating case 31 and a pair of seedling planting tools 32 attached to the left and right sides of the rotating case 31, respectively. The seedling on the outlet 26a is scraped off, and the scraped seedling is planted in the field. The rotary case 31 includes left and right rotary case bearings (on the left and right rotary case bearings (supporting portions fixed to the rear end of the planting transmission frame 29 with four fastening bolts 62). A bearing 64 is rotatably supported, and the outer periphery is covered with a rotation support case 63. Accordingly, the rotation support case 63 serves as a guard body that prevents mud, water, etc. from being applied to the case 31 due to the rotation of the rotation case 31. Furthermore, the rotating case 31 is less likely to come into contact with an operator or another structure, thereby improving safety and preventing the rotating case 31 from being damaged. Further, the rotation support case 63 can be detached from the planting transmission frame 29 together with the rotation case 31 by removing the four fastening bolts 62. Inside the rotation support case 63, fixed gears 65 of internal teeth located between the left and right bearings 64 are fixed by four fastening bolts 66. A rotation gear 67 that meshes with the fixed gear 65 is provided on the right side of the drive gear 61 so as to rotate around a rotation gear shaft 68 in the left-right direction provided in the rotation case 31. The rotating gear shaft 68 is provided so as to be deviated from the rotation center of the rotating case 31. Accordingly, as the rotary case 31 rotates, the rotary gear 67 rotates while revolving along the fixed gear 65, and the planetary gear mechanism is constituted by the rotary gear 67, the fixed gear 65, the rotary case 31, and the like. is doing. Further, an intermediate gear 69 that rotates integrally with the rotation gear 67 is provided on the left side of the drive gear 61, and a plurality (two) of planetary drive gears 70 that mesh with the intermediate gear 69 are provided in the rotation case 31. Further, each of the left and right planetary drive gear shafts 71 is provided to rotate. The first eccentric gear 72 that rotates integrally with the planetary drive gear 70 meshes with the second eccentric gear 73 that is the final gear. The planetary drive gear 70 and the first eccentric gear 72 constitute a counter gear. The pair of second eccentric gears 73 are provided so as to rotate integrally with the respective left and right final turning shafts 36 provided in the rotary case 31. The first eccentric gear 72 and the second eccentric gear 73 are not only eccentric but also have a non-circular shape with an irregular outer shape, and are transmitted to the final rotation shaft 36 while changing the rotational angular velocity. The pair of planetary drive gears 70, the first eccentric gear 72, the second eccentric gear 73, the planetary drive gear shaft 71, and the final rotation shaft 36 are symmetric with respect to the rotation center of the rotation case 31. The planetary gear is arranged at a position and rotates while revolving by the rotation of the rotary case 31.
[0033]
Incidentally, the rotation transmission ratio from the fixed gear 65 to the rotation gear 67 (that is, the ratio of the rotation speed of the rotation gear 67 to the rotation of the rotation case 31) and the rotation transmission ratio from the intermediate gear 69 to the planetary drive gear 70 are as follows. Since the rotation transmission ratio from the fixed gear 65 to the planetary drive gear 70 is 1, the planetary drive gear 70 rotates once in the same direction for each rotation of the rotation case 31. Yes. Further, the first eccentric gear 72 and the second eccentric gear 73 have the same number of teeth and a rotation transmission ratio of 1, and the final rotation shaft 36 is reversed while changing the rotation angular velocity for each rotation of the rotation case 31. Make one turn in the direction.
[0034]
The final rotation shaft 36 is supported by both left and right final rotation shaft bearings (bearings) 74 so as to be rotatable with respect to the rotation case 31. And the square shaft part of the both ends of the final rotation axis | shaft 36 is fitted in the square hole part of the seedling planting fixture fixing member 32c of the seedling planting tool 32, The said final rotation axis | shaft 36 and the said seedling planting tool 32 is rotated integrally, and the front / rear inclination posture of the seedling planting tool 32 is determined with respect to the rotational position of the rotary case 31. That is, the pair of left and right seedling planting tools 32 are configured to rotate integrally with the second eccentric gear 73. Therefore, while the rotation case 31 makes one rotation, the seedling planting tool 32 changes the front / rear inclination posture while rotating the rotation case 31 in the opposite direction to the rotation case 31. It is designed to rotate. The seedling planting tool 32 is provided with a seedling planting tool case 32a, and the seedling planting tool case 32a is fixed to the seedling planting tool fixing member 32c by two mounting bolts 32b. ing.
[0035]
Further, a rattling stop mechanism 40 is provided in the rotary case 31 in order to absorb backlash generated by backlash in the meshing of the gears in the rotary case 31. The backlash mechanism 40 is provided on the right side of the drive gear 61, and includes a backlash cam 40a that rotates integrally with the final rotation shaft 36, a backlash arm 40b that abuts on the cam 40a, and the arm 40b. A backlash spring 40c that biases the backlash cam 40a is provided. Accordingly, since the backlash cam 40a and the second eccentric gear 73 are distributed to the left and right of the drive gear 61, both 40a and 73 are arranged apart from each other on the left and right, and the final rotation shaft 36 on which both 40a and 73 act. Can be prevented, and the planting accuracy is improved. Note that both ends of the backlash spring 40c are connected to a pair of backlash arm 40b, and a plurality (two) of backlash arm 40b share the backlash spring 40c. By this rattling stop mechanism 40c, when the seedling planting device 22 scrapes off the seedling from the seedling scraping opening 26a and when the scraped seedling is planted in the field, the backlash of the second eccentric gear 73 due to the backlash is stopped to plant the seedling. The backlash of the tool 32 in the back-and-forth inclination posture is suppressed, and the seedling planting tool 32 scrapes off the seedlings properly so that the seedlings are accurately planted in the field. The backlash arm 40b is provided so as to rotate about a fulcrum shaft 40d provided in the drive gear 61, and the backlash spring 40c is provided in a hollow hole portion 61a communicating with the left and right provided in the drive gear 61. It is arranged overlapping with the space.
[0036]
The seedling planting tool 32 is an example of a planting claw 41 for scraping and holding one mat-shaped seedling and a seedling extrudate for extruding the seedling separated and held by the planting claw 41 toward a field scene. And a seedling extruding fork 42. The rotation of the rotary case 31 causes the seedling planting tool 32 to draw a long loop trajectory T in the vertical direction and pass through the seedling scraping opening 26a, thereby being secured to the seedling planting case 32a by the mounting bolt 43. The planted claw 41 scrapes and holds the seedling in the seedling scraping opening 26a.
[0037]
The seedling extrusion fork 42 includes a round shaft portion 42a that slides with respect to the seedling planting case 32a by an extrusion operation, and a seedling extrusion portion 42b that is fixed to the tip of the round shaft portion 42a. Composed. The front end portion of the seedling pushing part 42b is in contact with the seedling bed of the seedling held by the planting claw 41 so as to push out the seedling held by the planting claw 41.
[0038]
An upper portion of the seedling pushing fork 42, that is, a part of the round shaft portion 42a, is inserted into the seedling planting case 32a. In the seedling planting case 32a, a connection link 44 is connected to the upper end of the seedling push-out fork 42 via a lower support shaft 44a, and an upper support shaft 44b is connected to the connection link 44. The seedling push-out arm 45, the cam-side arm 46 provided integrally with the seedling push-out arm 45, and the seedling push-out cam 47 in contact with the cam-side arm 46. . The seedling push-out arm 45 and the cam side arm 46 swing integrally around a swing shaft 48 attached to the seedling planting case 32a. The connecting link 44 is connected to the seedling extruding fork 42 through the lower support shaft 44a. So that it hardly rotates. The seedling push cam 47 is provided so as to be rotatable around the final rotation shaft 36 of the rotary case 31 and is not integrally rotated with the rotary case 31. It is provided as follows. Therefore, the seedling pushing cam 47 is configured to rotate once relative to the seedling planting tool 32 for each rotation of the rotary case 31. Then, for each rotation of the seedling pushing cam 47 with respect to the seedling planting tool 32, the seedling pushing arm 45 swings by one reciprocation via the cam side arm 46, and the seedling pushing fork 42 takes one reciprocation. It is configured to slide. In addition, a rubber seal material 50 is provided in a portion where the seedling extrusion fork 42 slides in the seedling planting tool case 32 a, and the seedling extrusion fork 42 is provided by the seal material 50. Thus, the grease (lubricant) supplied into the seedling planting case 32a is prevented from being taken out of the seedling planting case 32a.
[0039]
A seedling extrusion spring 51 that is a compression spring is provided in contact with the upper end portion of the connection link 44. The other end of the seedling pushing spring 51 is in contact with the inner surface of the seedling planting case 32a. Further, the upper end portion of the connection link 44 constitutes a contact surface for the lower end portion of the seedling push spring 51 to contact. The seedling extruding fork 42 is biased toward the seedling extruding action side by the seedling extruding spring 51, and the seedling extruding cam 47 restricts the sliding of the seedling to the extruding action side. The slide 46 is slid by the seedling pushing spring 51 in a state where it is in contact with the small diameter portion 47b of the seedling pushing cam 47, and is pushed out. In addition, when it comes to the position of the bottom dead center A of the loop locus | trajectory T of the seedling planting tool 32, the said seedling pushing fork 42 is pushed out. Then, the seedling pushing fork 42 that has been pushed out by the time the seedling planting tool 32 rises from the position of the bottom dead center A and reaches the position of the seedling scraping opening 26a returns, and the planting claws 41 scrape the seedling. The seedling extruding fork 42 returns and operates until it is removed. A cushion rubber 52 that abuts the seedling extrusion arm 45 when the seedling extrusion fork 42 is pushed out is provided in the seedling planting case 32a. It is configured to mitigate the impact of the pushing operation of the seedling pushing fork 42 due to the above.
[0040]
Next, the rotation case 31 will be described.
The rotating case 31 is composed of left and right case bodies 31a. The case body 31a is a common part using the same one on the left and right. The left and right case bodies 31a are coupled by two case coupling bolts 75 (four in total) inserted from the left and right sides. The case coupling bolts 75 are arranged near the final rotation shafts 36 and at substantially symmetrical positions with respect to the shafts 36, and in the left and right case bodies 31 a or the entire rotation case 31. The position where the final rotation shaft bearing 74 is received is not easily displaced, and the position of the final rotation shaft 36 is accurately fixed to an appropriate position with respect to the rotation case 31. The final rotation shaft 36 and the case coupling bolt 75 pass through holes 61b corresponding to the respective positions provided in the drive gear 61 in the middle thereof, thereby improving the positional accuracy of the drive gear 61 with respect to the rotary case 31. At the same time, the positional accuracy of the final rotation shaft 36 with respect to the rotary case 31 and the drive gear 61 is improved.
[0041]
Referring to FIG. 7, a male screw portion 68a provided at one end (left end) of the rotary gear shaft 68 is screwed into a female screw hole portion 31b provided in the left case body 31a, and the rotary gear shaft 68 is also engaged. A male threaded portion 68b provided at the other end (right end) of the housing is projected out of the case, and a tightening nut 76 is screwed into the male threaded portion 68b from the outside of the case. Accordingly, the rotation gear shaft 68 that is the rotation axis of the rotation gear 67 and the intermediate gear 69 is supported and fixed at both ends by the left and right case bodies 31a, and similarly to the case coupling bolt 75. It is a coupling member that couples the left and right case bodies 31a. A rotating gear 67 and an intermediate gear 69 are integrally formed by a boss portion 77 provided on the outer periphery of the rotating gear shaft 68. Further, the rotation gear shaft 68 and the boss 77 pass through a hollow hole 61a inside the drive gear 61, and the intermediate gear 69 is passed through the hollow hole 61a from the rotation gear 67 side (right side in FIG. 7). The intermediate gear 69 is positioned on the opposite side of the drive gear 61 from the rotation gear 67 (left side in FIG. 7), and the rotation gear 67 and the intermediate gear 69 are mounted. Since the left and right case bodies 31a are common parts, the hole 31c for projecting the male screw portion 68b of the rotary gear shaft 68 to the outside of the case is provided in the other case body 31a (left side in FIG. 7). Although a cap 78 is inserted into the hole 31c, the lubricating oil in the rotating case 31 is prevented from coming out of the hole 31c.
[0042]
Further, a case coupling shaft 79 serving as a coupling member for coupling the left and right case bodies 31a is provided on the opposite side of the rotation gear shaft 68 from the rotation center of the rotation case 31. The case coupling shaft 79 is threadedly engaged with a female screw hole 31d provided in one case body 31a (left side in FIG. 7) with a male screw portion 79a provided at one end (left end in FIG. 7). The male threaded portion 79b provided at the other end (right end in FIG. 7) is projected out of the case from the shaft hole 31e provided in the case body 31a (right side in FIG. 7), and a tightening nut 80 is provided on the male threaded portion 79b. Are screwed in from the outside of the case. The case coupling shaft 79 passes through a hole 61 c provided in the drive gear 61 to improve the positional accuracy of the drive gear 61 with respect to the rotary case 31.
[0043]
Further, in order to fix the drive gear 61, which is supported inside one case body 31a (left side in FIG. 7) at a position symmetrical to the case coupling shaft 79 with respect to the rotation center of the rotation case 31. A fastening shaft 81 is provided. The fastening shaft 81 passes through a hole 61d provided in the drive gear 61, and is provided with a male screw portion 81a provided at one end (left end in FIG. 7) of the case body 31a (left side in FIG. 7). Projecting out of the case from the hole 31e, a fastening nut 82 is screwed into the male threaded portion 81a from the outside of the case to be fixed to the case body 31a, and provided at the other end (right end in FIG. 7). The fastening bolt 83 is screwed into the female screw hole 81b, and the drive gear 61 is fixed to one (left side in FIG. 7) case body 31a. Further, the planetary drive gear shaft 71 also passes through a hole 61e provided in the drive gear 61, and a male screw portion 71a provided at one end thereof (the left end in FIG. 7 and the lower end in FIG. 6) is a case body 31a (FIG. 7 is screwed into a female screw hole 31f provided on the inside (lower side in FIG. 6), and a tightening nut 84 is screwed into a male screw portion 71b provided at the other end (right end in FIG. 7, upper end in FIG. 6). However, the drive gear 61 is fixed to one case body 31a (left side in FIG. 7, lower side in FIG. 6). Therefore, the driving gear 61 is fixed to one case body 31a (the left side in FIG. 7 and the lower side in FIG. 6) by the tightening shaft 81 and the planetary driving gear shaft 71, and the position of the driving gear 61 is ensured. It is fixed to. Since the drive gear 61 is fixed to one case body 31a (left side in FIG. 7, lower side in FIG. 6), the left and right case bodies 31a are separated to divide the rotary case 31. The rotary case 31 can be divided by simply removing the four case coupling bolts 75 and the fastening nuts 76 and 80.
[0044]
Between the rotary case 31 and the rotary case bearing (bearing) 64, an interposition member is interposed between the rotary body 31 and the support portion 63 as shown in FIGS. A bush 85 is interposed. The bushes 85 are provided corresponding to the left and right case bodies 31a, respectively, and at the appropriate positions (two locations) on the outer left and right ends of the rotating case 31 on the rotation center side of the rotating case 31. The projection 85a is formed by being bent into a bent shape. On the other hand, as shown in FIG. 11, the left and right case bodies 31a are provided with grooves 31g at positions corresponding to the protrusions 85a at the outer left and right ends of the rotary case 31. Accordingly, when the bush 85 is attached to the rotating case 31, the protrusion 85a engages with the groove 31g to become an engaging portion between the rotating case 31 and the bush 85, and the bushing with respect to the rotating case 31. It becomes a detent that prevents the 85 from rotating. It should be noted that an oil sheath is provided on the left and right outer sides of the rotary case bearing (bearing) 64 so that the lubricating oil in the rotary case 31 is not released to the outside. -A ruling 86 is provided.
[0045]
The bush 85 for receiving the rotary case 31 and the seedling extrusion cam 47 for receiving the final rotary shaft bearing 74 are made of iron and have strength, and the rotary case 31 or the final rotary shaft 36 is firmly attached. We are sure to support it. Other structures such as the rotation case 31 and the rotation support case 63 are made of an aluminum casting to reduce the weight. The other structure may be made of resin instead of being made of aluminum casting.
[0046]
The fixed gear 65 is fixed inside the rotation support case 63 at an appropriate position. As shown in FIG. 5, the fixed gear 65 includes engaging portions composed of convex portions 65 a at a plurality of locations (four locations) on the outer periphery, and the convex portions 65 a are provided on the rotation support case 63 side. The rotation support case 63 is provided so as not to rotate by engaging with a recess (not shown) provided on the rotation support case 63.
[0047]
Between the seedling planting case 32a and the seedling extruding cam 47 of the seedling planting tool 32, a rubber boot 87 that can expand and contract so as to extend over the outer surfaces of both boss portions 32d and 47c in the left-right direction. Is provided. The boots 87 are mounted so that the end portions thereof are engaged with the boot grooves 47d provided on the outer surface of the seedling push cam 47 so as to be easily rotated, and the operation resistance of the seedling planting device 22 is not easily generated. The lubricating oil in the rotary case 31 or the seedling planting case 32a is prevented from leaking outside. In addition, between the inner surface of the boss portion 32d of the seedling planting case 32a and the outer surface of the seedling extrusion cam 47, and between the inner surface of the boss portion 47c of the seedling extrusion cam 47 and the final rotation shaft 36, Similarly, oil seals 88 and 89 are provided for preventing leakage of lubricating oil from the seedling planting case 32a or the rotating case 31, respectively.
[0048]
Further, as can be seen from FIG. 3 and the like, the rotation case 31 is accommodated in the internal space of the rotation support case 63, and the rotation support case 63 and the rotation case 31 are arranged so as not to overlap in a side view of the body. ing. Therefore, it is possible to remove the pair of seedling planting tools 32 on the left and right sides of the rotary case 31 from the final rotation shaft 36 and slide the rotary case 31 to the other side where the seedling planting tools 32 remain. it can. Since the boss portion 47c of the seedling push cam 47 is located on the rotation center side of the case 31 from the outer periphery of the rotation case 31 in a side view, the removal of the rotation case 31 is hindered. do not become.
[0049]
As described above, the seedling planting tool 32 is rotated by the rotation of the rotary case 31 and swung along the loop trajectory T in the vertical direction, and is planted by the planting claw 41 from the seedling scraping opening 26a below the seedling mounting table 20. Minute seedlings are scraped off and the scraped seedlings are transferred to the field scene, and the seedling extrusion fork 42 slides to push the seedlings into the field and plant them. In addition, in FIG. 10, the movement locus | trajectory U of the seedling planting tool 32 which considered the driving | running | working of the body is shown.
[0050]
The embodiment of the present invention has been described with respect to the riding type rice transplanter 1. However, the present invention is not limited to the riding type rice transplanter.
[Brief description of the drawings]
FIG. 1 is a side view of a riding type rice transplanter. FIG. 2 is a plan view of a riding type rice transplanter. FIG. 3 is a side view of a seedling planting apparatus. Fig. 5 is a side view showing a part of gears in a rotating case. Fig. 6 is a developed sectional view of a seedling planting device in the section S1-S1 in Fig. 5. Fig. 7 is a section in S2-S2 in Fig. 5. FIG. 8 is a cross-sectional view of the seedling planting apparatus taken along the S3-S3 cross section of FIG. 4. FIG. 9 is a side sectional view of the seedling planting tool. FIG. 11 is a side view showing the relationship between the case body of the rotating case and the bush. FIG. 12 is a side view showing the operation of the seedling planting device. FIG. 14 is a side view showing the state of the gear in the rotary case in the state of “1” in FIG. 12; FIG. 14 is a side view showing the state of the gear in the state of “2” in FIG. FIG. 15 is a side view showing the state of the gear in the case in an easy-to-understand manner. FIG. 15 is a side view showing the state of the gear in the rotating case in the state of “3” in FIG. FIG. 17 is a side view showing the state of the gear in the rotating case in the state of “4” in an easily understandable manner. FIG. 17 is a side view showing the state of the gear in the rotating case in the state of “5” in FIG. FIG. 18 is a side view showing the state of the gear in the rotary case in the state of “6” in FIG. 12 in an easy-to-understand manner.
DESCRIPTION OF SYMBOLS 22 ... Seedling planting device, 31 ... Rotation case, 32 ... Seedling planting tool, 36 ... Final rotation axis, 40 ... Backlash mechanism, 60 ... Input gear, 61 ... Drive gear, 65 ... Fixed gear, 67 ... rotating gear, 68 ... rotating gear shaft, 69 ... intermediate gear, 70 ... planetary driving gear, 71 ... planetary driving gear shaft, 72 ... first eccentric gear, 73 ... second eccentric gear

Claims (6)

The final gear (73) that revolves by the rotation of the rotating body (31) that rotates about the axis in the left-right direction rotates in the opposite direction to the rotating direction of the rotating body (31), and the final gear (73) integrally rotating manner NaeUe with tool in seedling planting apparatus in which a (32), rotating a gear meshed with the fixed gear tooth among fixed to the machine body side so as not to rotate against the inboard (65) (67) Is provided on the rotating body (31), and the rotating gear (67) rotates while revolving as the rotating body (31) rotates, and is transmitted from the rotating gear (67) to the final gear (73). A seedling planting device characterized by that.   The rotation transmission ratio from the fixed gear (65) to the rotation gear (67) and the rotation transmission ratio from the rotation gear (67) to the final gear (73) are set to reciprocal numbers. Seedling planting equipment.   The seedling planting tool (32) is attached to the left and right of the rotating body (31), and the input parts (60, 61) for inputting the rotational power to the rotating body (31) include left and right seedling planting tools (32). The seedling planting apparatus according to claim 1, wherein the seedling planting apparatus is located in the middle. The intermediate gear (69) provided on the rotating body (31) is transmitted from the intermediate gear (69) to the final gear (73) via the counter gear (70, 72 ) . 4. The structure according to claim 1, wherein the axis (71 ) of the counter gear (70, 72) and the axis ( 36 ) of the final gear (73) are not aligned with each other. 5. Seedling planting equipment.   The seedling planting device according to claim 3, characterized in that the rotary gear (67) and the final gear (73) are arranged in a lateral manner with respect to the input part (60, 61).   A backlash stop mechanism (40) for absorbing backlash of the final gear (73) due to the backlash of the gear is provided, and the backlash stop mechanism (40) and the final gear (73) are distributed to the left and right with respect to the input portions (60, 61). The seedling planting apparatus according to claim 3 or 5, wherein the seedling planting apparatus is arranged.

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