JP2009240317A - Rice transplanter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a rice transplanter capable of performing a stable transplanting work by improving the left and right balance of its machine body well. <P>SOLUTION: This rice transplanter is provided by having a construction constituted so that the transplanting part 15 is rotated around a rolling fulcrum shaft 97 to incline left and right by the rolling-regulating device 99 by equipping a rolling-regulating device 99 for regulating the left and right inclination of its transplanting part 15 and a seedling-conveying case 59 for driving the seedling-conveying shaft of a seedling-loading stand 16, and arranging by distributing the rolling-regulating device 99 at the one side of the transplanting part 15 and the seedling-conveying case 59 at the other side of the transplanting part 15 by centering around the rolling fulcrum shaft 97. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a rice transplanter that includes a seedling stage and a seedling planting claw and performs seedling planting work continuously.

  Conventionally, for example, Patent Document 1 includes a rolling control device that adjusts the horizontal inclination of a planting unit and a seedling feeding case that drives a seedling feeding shaft of a seedling stand, and the planting unit is rolled by the rolling control device. A structure that rotates around a fulcrum axis and tilts left and right is described.

Japanese Patent Laid-Open No. 7-184426

  In Patent Document 1, the rolling control device is arranged on the hitch bracket provided with the rolling fulcrum shaft, and the seedling feeding case is arranged on one side of the planting portion, so that the right and left balance of the machine body is poor and stable planting work. There is concern that cannot be done.

  This invention solves the said problem, and provides the rice transplanter which makes the right-and-left balance of a body good, and can perform the stable planting operation | work.

  In order to achieve the above object, a rice transplanter according to the first aspect of the present invention is a rice transplanter provided with a traveling vehicle equipped with an engine, and a planting unit including a seedling stage and a seedling planting claw, A rolling control device that adjusts the right and left tilt of the planting portion; and a seedling feeding case that drives a seedling feeding shaft of the seedling mounting table, and the rolling control device rotates the planting portion around a rolling fulcrum shaft. The rolling control device is arranged on one side of the planting part and the seedling feeding case is arranged on the other side of the planting part around the rolling fulcrum shaft. It is characterized by having made it.

  Further, the invention described in claim 2 is the rice transplanter according to claim 1, comprising left and right side frames for supporting the seedling platform, wherein the left and right side frames are provided on both the left and right sides of the hitch bracket. A rolling control device is arranged between the hitch bracket on which the rolling fulcrum shaft is arranged and one side frame, and connects the upper end side of the one side frame and the lower end side of the hitch bracket with a stay, while the other The seedling feeding case is arranged on the outside of the side frame, and a planting depth adjusting member for adjusting the planting depth of the seedling is arranged between the other side frame and the hitch bracket. Is.

  According to invention of Claim 1, in the rice transplanter which provided the traveling vehicle carrying an engine and the planting part provided with a seedling stand and a seedling planting claw, the horizontal inclination of the said planting part is adjusted. A structure comprising a rolling control device and a seedling feeding case for driving a seedling feeding shaft of the seedling mounting table, and configured so that the planting part is rotated about a rolling fulcrum shaft and tilted left and right by the rolling control device. Since the rolling control device is arranged on one side of the planting part and the seedling feeding case is distributed on the other side of the planting part around the rolling fulcrum shaft, the rolling control is performed. By incorporating the device and the seedling feeding case into the planting part with a good balance between the left and right sides, it is possible to improve the planting accuracy while improving the overall balance of the machine body and enabling stable traveling.

  According to the invention described in claim 2, the left and right side frames for supporting the seedling stage are provided, and the left and right side frames are provided on both the left and right sides of the hitch bracket, and the rolling fulcrum shaft is disposed. A rolling control device is arranged between the hitch bracket and one side frame, and the upper end side of the one side frame and the lower end side of the hitch bracket are connected by a stay 110, while the other side frame is outside. A lightweight structure in which the seedling feeding case is arranged, and a planting depth adjusting member for adjusting the planting depth of the seedling is arranged between the other side frame and the hitch bracket. However, the rigidity of the right side frame can be improved to ensure rolling performance.

Whole side view of rice transplanter. Overall plan view of rice transplanter. The side view of a planting part. The top view of a planting part. Plane explanatory drawing of a planting part. The schematic front view of a planting part. The front view of a planting frame part. The side view of a planting frame part. Plan sectional drawing of a planting frame part. The planting frame left side top view. The right side top view of a planting frame. Cross-sectional explanatory drawing of a planting frame. The perspective explanatory view of a planting frame. Explanatory drawing of a seedling extraction part. Cross-sectional explanatory drawing of a seedling feeding case part. Explanatory drawing of a transmission shaft part. Explanatory drawing of a switching mechanism. Explanatory drawing of a planting claw unit clutch part. External appearance explanatory drawing of a planting claw unit clutch part. Explanatory drawing of a side bumper part.

  Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is a side view of a riding rice transplanter, and FIG. 2 is a plan view thereof. In FIG. 1, reference numeral 1 denotes a traveling vehicle on which an operator is boarded. The front paddy field traveling wheel 6 is supported in front of the case 4 via the front axle case 5 and the rear axle case 7 at the rear of the transmission case 4 is supported by the rear wheel case 8 for paddy field traveling. The spare seedling platforms 10 are attached to both sides of the bonnet 9 covering the engine 2 and the like, and the mission case 4 and the like are covered by a vehicle body cover 11 on which an operator rides. A seat 13 is attached, and a steering handle 14 is provided at the rear of the bonnet 9 in front of the driver seat 13.

  In the figure, reference numeral 15 denotes a planting part having a seedling mounting table 16 for four-row planting and a plurality of seedling planting claws 17, and the like. The planting frame 20 is supported by the planting frame 20 through the lower rail 18 and the guide rail 19 so as to be slidable in the left and right directions, and a rotary case 21 that rotates at a constant speed in one direction is supported by the planting frame 20. A pair of nail cases 22 and 22 are arranged at symmetrical positions around the axis, and seedling planting nails 17 and 17 are attached to the tips of the nail cases 22 and 22. Further, left and right side frames 23 and 23 are erected on both the left and right ends of the planting frame 20 to support the seedling mounting table 16, and a hitch bracket 24 at the center of the planting frame 20 includes a top link 25 and a lower link 26. The hydraulic lifting cylinder 28 provided on the traveling vehicle 1 is connected to the lower link 26 via the lifting link mechanism 27, and the planting unit 15 is lifted and lowered via the link mechanism 27 when the lifting cylinder 28 is driven. When the planting part 15 is lowered, one seedling is taken out by the planting claws 17 from the seedling mount 16 that is reciprocated to the left and right, and the seedling planting operation is continuously performed.

  In the figure, 29 is a main speed change lever, 30 is a seedling lever that enables operations such as travel stop at the position where the aircraft is lowered as well as the boarding position, 31 is a planting lift lever, and 32 is a main clutch. Pedals 33 and 33 are left and right brake pedals, 34 is a center float for leveling two strips, 35 is a side float for leveling one strip, 36 is a side strip fertilizer for four strips, 37 and 37 are rear wheel 8 Auxiliary wheels to be deployed on the outside.

  The fertilizer for side strip 36 includes a fertilizer hopper 38 for feeding fertilizer, a fertilizer feed case 39 that is a fertilizer feed section for supplying fertilizer, and a flexible transport hose 41 to the side strip groover 40 of the floats 34 and 35. A blower 42 for discharging fertilizer and a cylindrical air tank 43, and a blower 42 is attached to the right end of the air tank 43, and four sets of four fertilizer feeding cases 39 are arranged above the air tank 43. The upper end of the seedling stage 16 is arranged close to the rear side of the fertilizer hopper 38.

  As shown in FIG. 3 to FIG. 12, the planting frame 20 includes left and right vertical frames 44a and 44b made of two pipes and a horizontal frame 45 made of pipe that connects the front ends of the left and right vertical frames 44a and 44b. A cruciform frame joint (cross pipe joint) 46 formed by bulging is welded and fixed to the distal ends of the vertical frames 44a and 44b, and the rotary case 21 is rotatably supported by the joint 46 via a rotary shaft 47; The left and right cruciform frame joints (cross pipe joints) 48a and 48b formed by bulging are welded and fixed to the vertical frames 44a and 44b and the horizontal frame 45, and these vertical and horizontal frames 44a, 44b, and 45 are integrally connected and lightweight. The planting frame 20 is formed at a low cost.

  In addition, a planting input shaft 49 is provided at the front end of the right frame joint 48b, and the driving force from the PTO shaft of the transmission case 4 is transmitted to the input shaft 49 via the universal joint shaft 50 and installed in the horizontal frame 45. The input shaft 49 is linked to the planting drive shaft 51 via bevel gears 49 a and 52, and the planting claw drive shaft 53 provided in the left and right vertical frames 44 a and 44 b is planted via the bevel gears 52 and 54 and the safety clutch 55. The seedling planting claw 17 is driven by being coupled to the drive shaft 51 and interlockingly coupled with the rotating shaft 47 via the bevel gears 56a and 56b and the planting claw unit clutch 57. ing.

  Further, a seedling feed shaft 58 for laterally feeding the seedling stage 16 in the horizontal direction and vertical feeding of the seedlings on the seedling stage 16 is linked to the left end of the planting drive shaft 51 through a seedling feeding case 59 made of aluminum die cast. The one end side flange portion 61 of the seedling feeding case 59 is bolted and fixed to the flange portion 60 which is the left end mounting portion of the left frame joint 48a, and the left end of the seedling feeding shaft 58 is inserted into the other end side of the case 59. A speed change mechanism 64 formed by two sets of high and low speed change gears 62 and 63 is interposed between the drive shaft 51 and the seedling feed shaft 58 in the case 59, and the left side of the seedling feed shaft 58 with respect to the substantial center of the machine body. Half of the seedling vertical feed camshaft 65 and the right half of the seedling stand horizontal feed screw shaft 66 are provided so that the seedling feed base 58 can be fed laterally when the seedling feed shaft 58 is driven to rotate at high and low speeds. It is configured to feed seedlings vertically.

  10 and 11, a planting depth adjustment fulcrum shaft 67 is pivotally supported on the lower side of the front end of the planting frame 20, and brackets 68 and 69 on the upper surfaces of the rear ends of the floats 34 and 35 are mounted. Is connected to the fulcrum shaft 67 through the planting depth adjustment links 70 and 71, and a change in the float inclination angle (planting depth) is detected by the elevating link 72 coupled to the front end of the center float 34, and the fulcrum A reference planting depth is adjusted by a planting depth adjusting lever 73 having a base end fixed to the shaft 67.

  Note that L-shaped left and right side bumpers 74 are provided on the left and right ends of the fulcrum shaft 67 so as to be foldable outwardly through mounting members 75.

  As shown in FIGS. 8, 10, and 11, the base end of the left and right marker support stay 77 that supports the left and right muscle pulling marker 76 so as to be foldable (cantilever) is welded and fixed to the outer upper surface of the left and right frame joints 48 a and 48 b. The stay 77 is formed of an L-shaped pipe, and the longitudinal stay 77a in the front-rear direction is welded and fixed to the substantially same height surface in the longitudinal direction at the joints 48a and 48b by line contact, and the lateral stay 77b is secured to the longitudinal frame. 44a and 44b are faced to the left and right outwards, the marker 76 is supported by the mounting shaft 78 at the end of the lateral stay 77b via a marker base 79, and the lateral stay 77b of the left stay 77 is fed as a seedling feeding case. The case 59 is constructed so as to be positioned in front of 59.

  Further, as shown in FIG. 13, the support stay 77 is welded at the base end of the vertical stay portion 77a to the inner surfaces of the left and right reinforcing members 80 and 81 for attaching the base ends of the left and right side frames 23 and 23 to the joints 48a and 48b. The support strength of the side frame 23 and the stay 77 is improved by being fixed.

  As shown in FIG. 14, a seedling adjustment plate 83 that adjusts the amount of seedling removal by moving the seedling extraction plate 82 at the lower end of the seedling mounting table 16 is moved up and down via a guide rod 85 on the guide member 84 of the planting frame 20. An engagement plate 87 that is movably supported and engaged with the hook 86 of the adjustment plate 83 is provided on the left and right seedling collection amount adjusting shaft 88, and is connected to the left end side of the seedling collection amount adjustment shaft 88. The operation of 89 is to adjust the amount of seedlings for one stock taken out by the seedling planting claws 17. The bearing plate 90 fixed to the seedling feeding case 59 and the right reinforcing member 81 are provided with a seedling amount adjusting shaft 88. The left and right ends of the horizontal shaft portion 88a are rotatably supported, and the left end side of the horizontal shaft portion 88a is bent forward at approximately 90 degrees outward from the seedling feeding case 59 to form a vertical axis portion 88b in the front-rear direction. Then, in front of the seedling feeding case 59, the front end of the vertical axis 88b is folded inward at approximately 90 degrees. Then, the lever mounting portion 88c is formed, and the base end of the L-shaped adjustment lever 89 is fixed to the mounting portion 88c with two bolts 91, and the tip of the lever 89 is extended upward and obliquely forward via the lever guide 92. It is provided so as to face between the left rear wheel 8 and the auxiliary wheel 37 and surrounds and protects the seedling feeding case 59 with each part 88a, 88b, 88c, and a gap 93 between the case 59 and the seedling amount adjustment shaft 88 is provided. The conveyance hose 41 is configured to be positioned.

  The hitch bracket 24 has upper and lower link shafts 94 and 95 that connect the top link 25 and the lower link 26, and a fulcrum member 96 that is held and fixed to the approximate center of the horizontal frame 45 of the planting frame 20 by a lower end of the bracket 24. And a hydraulic rolling cylinder 99 is attached to a mounting seat 98 at the upper end of the bracket 24, and the tip of the piston rod 100 of the cylinder 99 is connected to the fixed bracket 101 at the upper end of the right side frame 23. A gear pump 102 that reciprocates the double-acting cylinder 99, a reversible electric motor 103 that drives the pump 102 in the forward and reverse directions, and an oil tank 104 are integrally provided in the cylinder 99, and are fixed to the upper surface of the mounting seat 98. Rolling correction spring between the receiving plate 105 to be provided and the left and right brackets on the back side of the seedling table 16 When the pendulum type rolling sensor 108 provided on the sensor base 107 of the lateral frame 45 on the left side of the hitch bracket 24 detects the inclination of the planting portion 15, the piston rod 100 of the cylinder 99 is controlled to advance and retract. The planting part 15 is swung left and right around the fulcrum shaft 97 so that the planting part 15 is horizontally held.

  Also, a bracket 109 that is welded and fixed to the horizontal frame 45 and the right end of the fulcrum member 96 is provided, and the bracket 109 and the bracket 101 at the upper end of the right side frame 23 are reinforced and connected by an oblique stay 110, so that it has the lightest structure. Thus, the rigidity of the right side frame 23 is improved to ensure the rolling performance.

  Further, the bracket 109 is used to rotatably support substantially the middle of the seedling feed shaft 58, and the both ends of the lateral feed screw shaft 66 are interposed between the bearing plate 111 fixed to the right support stay 77 and the bracket 109 via a bearing 112. The vertical feed cam shaft 65 and the screw shaft divided into the left and right are supported and supported by connecting the right end of the vertical feed cam shaft 65 to the left end of the screw shaft 66 via the joint 113 and the left end to the seedling feed case 59. 66 has a double-supported structure to improve the support strength, and the right end of the longitudinal feed cam shaft 65 is connected to the screw shaft 66 with the same axis to improve the longitudinal feed accuracy. The cam shaft 65 is an iron hollow pipe and the screw shaft 66 is made of solid iron material. The seedling feeding case 59 and the cam shaft 65 are arranged on the left side of the center of the machine body, and the heavy screw shaft 66 is arranged on the right side. The left and right balance is made good.

  Further, a slider 114 is screwed to the screw shaft 66, and the slider 114 is connected to the seedling mounting table 16 via a slider receiver 115, so that the seedling mounting table 16 is rotated when the screw shaft 66 rotates in one direction. The vertical feed cam shaft 65 has left and right vertical feed cams 116. When the seedling stage 16 moves to the left and right moving ends, the vertical feed cam 116 contacts the driven cam 117 in one direction. A longitudinal feed belt 123 wound around the longitudinal feed rollers 121 and 122 of a pair of upper and lower roller shafts 119 and 120 provided on the lower end side of the seedling stage 16 by rotating the longitudinal feed roller shaft 119 in one direction via the clutch 118. It is comprised so that it may move to the lower end direction for 1 seedling.

  As shown in FIGS. 15 to 17, the frame joint 48 a for connecting the seedling feeding case 59 is provided with a flange portion 60 for attaching and fixing the seedling feeding case 59 on one end side of the frame joint 48 a, and has a fixed length from the flange portion 60. An inlay fitting portion 124 that fits to the outer end of the frame joint 48 a that protrudes is provided on the inner surface of one side of the seedling feeding case 59, and a tapered surface 125 is formed on the outer end of the fitting portion 124. Is interposed between the tapered surface 125 and the joint 48a so that the airtightness between the joint 48a and the case 59 can be maintained by a simple and low-cost means when the flanges 60 and 61 are fixed by the bolts 127.

  The seedling feeding case 59 is provided with a transmission shaft 128 separate from the planting drive shaft 51, a spline hole 129 is formed inside the bevel gear 52, and the left end of the drive shaft 51 and the transmission shaft 128 are formed in the spline hole 129. The transmission shaft 128 is integrally connected to the drive shaft 51 by fitting with the right end so that the transmission shaft 128 can be easily and integrally removed when the seedling feed case 59 is removed.

  Further, a bearing 130 is interposed between the joint 48a and the bevel gear 52, the bevel gear 52 is rotatably supported at one end of the joint 48a, and a flange portion 60 is provided on the outer surface of the joint 48a at the outer end from the bearing 130 position. The inner diameter b of the inner peripheral surface of the joint 48a for welding the flange portion 60 is larger than the inner diameter a of the fitting surface of the joint 48a to which the bearing 130 is fitted and fixed (a <b). Even if the joint 48a is slightly deformed by welding distortion, the assembly of the bearing 130 is not adversely affected.

  Further, the seedling feeding case 59 is formed in an L shape having a vertical case portion 59a and a horizontal case portion 59b, a flange portion 61 is formed at the right end of the horizontal case portion 59b, and the switching gears 62 and 63 are formed in the vertical case portion 59a. The transmission mechanism 64 is formed by incorporating a transmission switching mechanism 131 into the lateral case portion 59b. The switching gears 62 and 63 are driven-side gears 62a and 63a that are idle-supported on the transmission shaft 128, and a longitudinal feed cam shaft 65. The switching mechanism 131 is embedded in the key groove 132 of the transmission shaft 128 and the tip thereof is selected by the force of the seat spring 133 as the key groove 134 of the gears 62a and 63a. And a shift lever 138 connected to the shift key 135 via a shift ring 136 and a shifter 137. -The left end operation portion 138a of 138 is projected to the front left side of the seedling feeding case 59, and the lateral feed speed of the high / low / second speed is switched by pushing and pulling the switching lever 138 in the left / right direction. .

  Further, the switching gears 62 and 63 are formed of a metal material such as iron in the gears 62a and 63a on the side engaged with the shift 135 and the gears 62b and 63b on the other side are formed of a resin material to reduce weight and durability. It is configured to improve both.

  As shown in FIGS. 18 and 19, the planting frame 20 is compactly assembled with the bevel gears 49a, 52, and 54 in the front frame joints 48a and 48b, and the bevel gears 56a are compactly incorporated into the rear frame joint 46. 56b and planting claw unit clutch 57 are incorporated so as to simplify the structure and reduce the cost. The planting claw unit clutch 57 has a fixed clutch portion 139 on a bevel gear 56b that is loosely supported on a rotating shaft 47. The movable clutch portion 141 is formed on the slide body 140 that is spline-fitted to the rotary shaft 47 so as to be slidable to the left and right, and the clutch portion 139 and 141 are normally coupled by pressing the slide body 140 by the clutch spring 142 (ON). And the clutch operating member 143 for retracting the sliding body 140 against the force of the spring 142 is provided with the frame joint 46. The operation member 143 is provided so as to be able to advance and retreat, and the planting claw unit clutch 57 is turned on and off by operating the clutch lever by connecting the operation member 143 to a unit clutch lever (not shown) on the back side of the seedling table 16 via a lever 144 or the like. It is configured as follows.

  As shown in FIGS. 20 (1) and 20 (2), the side bumper 74 is mounted by inserting a bumper bent vertical portion 74a vertically movable into a U-shaped mounting member 75 fixed to both ends of the fulcrum shaft 67. A compression spring 146 is interposed between the spring seat 145 of the vertical portion 74a projecting downward from the member 75 and the mounting member 75, and an L-shaped position restricting plate 147 that abuts on the left end surface and the front surface of the mounting member 75 is vertical. A stopper portion 148 that is fixed to the portion 74a and prevents the regulating plate 147 from rotating backward is provided on the mounting member 75, and the bumper horizontal portion 74b is supported at the fulcrum shaft at the contact position between the regulating plate 147 and the left end surface of the mounting member 75. 67, the seedling extraction plate 82 and the like are protected in a protruding state, while the bumper 74 is pulled up against the spring 146 and the horizontal portion 74b is rotated forward by approximately 90 degrees to thereby restrict the plate 147 and the mounting member. 7 Are configured to front and enables easily loading and storage of the transport vehicle by reducing the body width when the bumper storage position to abut.

  By the way, the inside of the seedling feeding case 59 is composed of two shafts 65 and 128, and covers the two transmission gears 62 and 63 and the simple transmission mechanism 64 and the switching mechanism 131 of the shift key 135, so that the mold cost is kept low. Low cost, small size and light weight, and the case lid 150 on the left side surface fixed to the case body via the bolt 149 is removed to facilitate the replacement and inspection of the gears 62 and 63, thereby improving maintenance. be able to.

  In addition, when using the tools for attaching and detaching the bolt 127 by making the horizontal case portion 59b into a long shape and increasing the distance between the vertical case portion 59a and the flange portion 61, the tools are used. The case 59 can be easily inserted up to the position of the bolt 127 so that the case 59 can be easily attached and detached.

  As described above, the planting portion 15 is formed by forming the planting frame 20 with a pipe frame to simplify the configuration and reduce the weight. The planting frame 20 that drives the seedling planting claws 17 and the left and right muscles And a marker support member 77 that is a marker support stay that supports the pull marker 76 in a foldable manner. The rear end of the marker support stay 77 is fixed to the planting frame 20, and the front end side is bent outward from the body. Thus, without changing the support angle of the marker 76 every time the planting depth is adjusted as in the past, and during the storing operation of the marker 76, the fertilizer that is a fertilizer applied to the seedling table 16 and the machine Without the inconvenience of bringing the marker 76 into contact with the device 36, the marker 76 is incorporated into the planting part 15 in a compact manner to shorten the front and rear length of the machine body so that the front and rear balance of the machine body is good, and the storing posture of the marker 76 is improved. Compared to the conventional posture, the muddy soil adhering to the marker 76 is prevented from scattering to the operator side during the marker storing operation, and the planting frame 20 is used by appropriately changing the bending position of the marker support stay 77. Costs can be reduced by making it possible to expand to other models and specifications that share parts.

  Further, by fixing the longitudinal line contact portions of the marker support stays 77 to the outer surfaces of the frame joints 48a and 48b for connecting and fixing the planting frame 20, the marker support stays are attached to the outer surfaces of the frame joints 48a and 48b. 77 can be held with high strength, and the durability of the marker 76 can be improved.

  Further, by fixing the marker support stay 77 to the side frame 23 that supports the seedling table 16 and the reinforcing members 80 and 81 of the frame joints 48a and 48b, a special reinforcing member for the marker supporting member is not provided. The marker support stay 77 can be firmly fixed to the frame joints 48a and 48b, and the strength of the marker support stay 77 can be improved by a lightweight and low-cost means.

  In addition, the planting frame 20 that drives the seedling planting claws 17, the seedling feeding case 59 that is arranged on one side of the planting frame 20 to drive the seedling feeding shaft 58, and the left and right muscle pulling marker 76 are freely foldable. A marker support stay 77 for supporting the marker support stay 77, the rear end of the marker support stay 77 is fixed to the planting frame 20, the front end is bent outward from the machine body, and the marker support stay 77 is a bent portion. By arranging the horizontal stay portion 77b in front of the seedling feeding case 59, the support angle of the marker 76 is not changed every time the planting depth is adjusted as in the conventional case, and also during the storing operation of the marker 76. In addition, without the inconvenience of bringing the marker 76 into contact with the fertilizer 36 that is installed in the machine, the marker 76 is incorporated in the planting portion 15 in a compact manner to shorten the longitudinal length of the machine body and to improve the longitudinal balance of the machine body. In both cases, the storage position of the marker 76 is set to an upright position as compared to the prior art to prevent the mud soil adhering to the marker 76 from scattering to the operator side during the marker storage operation, and the bending position of the marker support stay 77 is appropriately set. By changing, it is possible to expand to other models and other specifications that use parts such as planting frames in common, and cost reduction is achieved. Furthermore, the front of the seedling feeding case 59 is protected by the marker support stay 77 and the seedling feeding case 59 can be prevented from being damaged and durability can be improved.

  Further, by arranging a seedling feeding case 59 between a side bumper 74 which is a protective member provided on one end side of the fulcrum shaft 67 which is a float support member and the marker support stay 77, the bumper 74 and the marker support stay 77 are When the seedling feeding case 59 is protected from the front and back, the seedling feeding case 59 can be satisfactorily installed without damage, and the switching lever 138 for switching the lateral feed speed is provided in the seedling feeding case 59, It is possible to eliminate the concern that foreign matters are caught on the switching lever 138 and to prevent erroneous operation of the switching lever 138.

  Further, a planting frame 20 that drives the seedling planting claws 17, frame joints 48a and 48b that connect and fix the planting frame 20, and a seedling feeding case that drives a seedling feeding shaft 58 that performs lateral feeding and vertical feeding of seedlings. 59, and a flange portion 60 for attaching and fixing the seedling feeding case 59 is provided on one end side of the frame joint 48a, and the spigot fitting portion 124 that is fitted to the outer end of the frame joint 48a projected from the flange portion 60 is provided as a seedling. By being provided on the inner surface of the feed case 59, the planting portion of the seedling feed case 59 is integrally formed while leaving the switching gears 62 and 63 for lateral feed speed change and the switching mechanism 131 in the seedling feed case 59. Can be easily attached to and detached from the side to improve the attachment accuracy of the seedling feed case 59, and the lateral feed transmission such as the switching gears 62 and 63 and the switching mechanism 131 can be used. 64 maintenance can be improved.

  Further, a bearing 130 that is a bearing member that supports the drive shaft 51 that is a drive member in the planting frame 20 is provided on the inner surface on one end side of the frame joint 48 a, and the flange portion 60 is fixed to the frame joint 48 a at the outer end from the bearing 130. In addition, when the inner diameter of the frame joint 48a is set larger than the bearing 130 position on the flange portion 60 position side and the flange portion 60 is fixed to the frame joint 48a by welding, the frame joint 48a is slightly deformed by welding distortion. However, the assembly of the bearing 130 with good accuracy is performed without causing any trouble in the assembly of the bearing 130.

  Furthermore, a tapered surface 125 which is a tapered portion is formed on the inner surface of the flange portion 61 of the seedling feeding case 59 fixed to the flange portion 60, and an O-ring 126 is interposed between the flange portion 60 (joint 48a) and the tapered surface 125. Thus, the structure is simple and low-cost compared to conventional oil seals and the like, and even if the frame joint 48a is deformed due to welding distortion, airtightness is ensured without additional processing, and the tapered surface 125 The seedling feeding case 59 can be easily and accurately positioned by the reaction force of the O-ring 126.

  The planting frame 20 that drives the seedling planting claws 17 and the seedling feeding case 59 that is arranged on the left and right sides of the planting frame 20 and drives the seedling feeding shaft 58 are provided. A transmission mechanism 64 that is formed in a substantially L-shape of a horizontal case portion 59b that is connected to the attached frame 20 and a vertical case portion 59a that is connected to the seedling feed shaft 58 is used as a transmission mechanism. By providing a switching mechanism 131 for switching 64 in the lateral case portion 59b, it is possible to easily change the lateral feeding speed of the seedling mounting table 16 by the seedling feeding case 59 provided at a low cost and in a small size, and the periphery of the seedling feeding case 59 Space is secured, the degree of freedom of design and accessory installation is increased, and the case 59 can be easily removed while leaving the speed change mechanism 64 and the switching mechanism 131 in the seedling feed case 59. It is not able to improve the maintainability of such transmission mechanism 64 and the switching mechanism 131.

  Further, the transmission mechanism 64 is formed of a plurality of sets of switching gears 62 and 63, the gears 62a and 63a on the side operated by the switching mechanism 131 are formed of metal, and the mating gears 62b and 63b are formed of resin. The combination of the gears 62a, 62b, 63a, and 63b made of the gear 62a, 63a and 63b suppresses friction and enables smooth rotation and weight reduction, and the strength on the side of the gears 62a and 63a when the shifter 137 or the like is used for the switching mechanism 131 The shortage can be solved, and the gears 62 and 63 can be kept in a small shape to prevent the seedling feeding case 59 from being enlarged.

  Further, a planting frame 20 that drives the seedling planting claws 17, a seedling feeding case 59 that is arranged on the left and right sides of the planting frame 20 and drives the seedling feeding shaft 58, and a seedling amount of the seedling mounting table 16 A seedling amount adjusting shaft 88 that is a seedling amount adjusting member for adjusting the seedling amount, by detouring the side from the rear of the seedling feeding case 59 and projecting the front end side of the seedling amount adjusting shaft 88 forward, The outside of the seedling feeding case 59 is protected by a seedling feeding amount adjusting shaft 88 to improve the durability of the seedling feeding case 59, and the seedling feeding amount adjusting shaft 88 is used as a guide member for the fertilizer hose 41 when the fertilizer 36 is mounted. By utilizing this, it is possible to enable good support without damage to the hose 41.

  Furthermore, the seedling amount adjusting shaft 88 is formed in a structure in which a horizontal shaft portion 88a which is a horizontal member and a vertical shaft portion 88b which is a vertical member are integrally combined in a substantially L shape, thereby reducing the number of parts. By forming the seedling amount adjustment shaft 88 to facilitate the assembly and reduce the cost, and by forming the connecting portion of the horizontal shaft portion 88a and the vertical shaft portion 88b in a curved bent portion, It is also possible to prevent inconveniences such as catching on foreign matters.

  Furthermore, the reinforcing member 80/81 of the side frame 23 that supports the seedling mounting table 16 is supported by the seedling amount adjusting shaft 88, and the number of parts of the supporting member that supports the seedling amount adjusting shaft 88 is reduced. The structure can be simplified and the cost can be reduced.

  In addition, a seedling amount adjustment lever 89 that is a seedling amount adjustment operation member for adjusting the seedling amount of the seedling mount 16 is provided on the side of the planting portion 15, and outward of the rear wheel and toward the front of the body. By projecting the operation portion of the adjustment lever 89, the amount of twisting of the operator's body from the driver's seat position is suppressed as much as possible to improve the operability of the seedling collection amount adjustment lever 89, and the amount of seedling adjustment is adjusted. The arrangement can be facilitated by increasing the degree of freedom of the rotation angle of the lever 89.

  Further, the seedling amount adjusting lever 89 is disposed between the rear wheel 8 and the auxiliary wheel 37 on the outside, so that the limited space between the rear wheel 8 and the auxiliary wheel 37 is effectively used, and the seedling amount adjusting lever 89 is used. It is possible to make it possible to easily incorporate a compact into the planting part 15.

  Furthermore, a seedling adjustment lever 89 is arranged on one side of the rear wheel 8, and a planting depth adjustment lever 73, which is a planting depth adjusting operation member that adjusts the planting depth on the other side by holding the rear wheel 8. Accordingly, these levers 73 and 89 that require an operation during work can be arranged close to the same side with respect to the center of the machine body, thereby improving their operability.

  Moreover, the planting frame 20 that drives the seedling planting claw 17 and a seedling feeding shaft 58 that is a seedling feeding member connected to the planting frame 20 via a seedling feeding case 59 are provided, and the seedling feeding shaft 58 is provided at one end side. The longitudinal feed cam shaft 65 is formed with a lateral feed screw shaft 66 on the other end side, and the cam shaft 65 and the screw shaft 66 are arranged to the left and right from the center of the machine body. To improve the stability of seedling planting, and to maintain the vertical feeding cam 116 of the vertical feeding cam shaft 65 and the slider 114 of the horizontal feeding screw shaft 16 from the center of the machine to the left and right to facilitate the maintenance thereof. be able to.

  Further, both ends of the lateral feed screw shaft 66 are connected to and supported by the planting frame 20, and both ends of the vertical feed cam shaft 65 are supported by the screw shaft 66 and the seedling feed case 59, so that the seedling feed case 59 and the lateral feed are fed. The screw shaft 66 is supported by the planting frame 20 with good accuracy, and the vertical feed cam shaft 65 is supported by the seedling feed case 59 and the screw shaft 66 in a supported manner so that the seedling mounting table 16 is laterally fed and the seedling is vertically fed. Accuracy can be improved.

  Further, the seedling feeding case 59 is formed in a substantially L-shaped structure having a horizontal case portion 59b for connecting the seedling feeding case 59 to the planting frame 20 and a vertical case portion 59a in the vertical direction, and the vertical feed cam shaft is formed inward from the vertical case portion 59a. 65, and the vertical feed cam 116 faces a substantially U-shaped space formed by the seedling feed case 59 and the cam shaft 65, so that the lateral width of the seedling feed case 59 and the vertical feed cam portion is increased. It is possible to reduce the size and increase the degree of freedom in installing and designing other components.

By the way, conventionally, for example, there is a means for transmitting the rotation of the planting drive shaft in the planting frame to the lateral feed shaft through the lateral feed case to laterally feed the seedling stage, but it is intended to change the lateral feed speed. In addition to being troublesome, such as changing the gear in the transverse feed case and making it cumbersome, the gear and shaft will remain on the planting side even if the case cover is removed during maintenance inspection of the gear. Since it remains, there is a problem that it is troublesome and requires the removal of the gear and the shaft each time.
Also, a lateral feed speed change mechanism comprising a plurality of sets of switching gears is provided in the planting drive case for inputting the PTO drive force from the machine side, and the speed change output from the speed change mechanism is transmitted to the lateral feed shaft to transmit the lateral feed speed change mechanism. There is a means for changing the feed rate, but there is a problem that the structure is complicated and the case becomes large, resulting in an increase in weight and cost.
Furthermore, when multiple sets of gears for shifting are provided in the transverse feed case and both of the sets of gears are made of resin, the friction becomes so large that the gears cannot be rotated smoothly. There are concerns. In addition, when a shifter is used as the switching mechanism of the switching gear, the gear acting on the shifter is insufficient if the resin is made of resin, and when securing a certain strength or more, the case becomes larger by increasing the thickness of the gear, etc. There were problems such as concerns.

  As described above, the planting frame 20 that drives the seedling planting claw 17 and the seedling feeding case 59 that is disposed on the left and right sides of the planting frame 20 and drives the seedling feeding shaft 58 are provided. 59 is formed in a substantially L-shape of a horizontal case part 59b connected to the planting frame 20 and a vertical case part 59a connected to the horizontal feed shaft 58, and a transmission mechanism 64 for changing the seedling feed speed is provided in the vertical case part 59a. Since the switching mechanism 131 for switching the speed change mechanism 64 is provided in the lateral case portion 59b, the seedling feeding case 59 provided at a low cost and in a small size can easily change the seedling feeding speed, and the periphery of the seedling feeding case 59 Space is secured, the degree of freedom of design and accessory installation is increased, and the case 59 can be easily removed while leaving the speed change mechanism 64 and the switching mechanism 131 in the seedling feed case 59. It is capable of improving the maintainability of such transmission mechanism 64 and the switching mechanism 131 by.

  Further, the transmission mechanism 64 is formed by a plurality of sets of switching gears 62 and 63, the gears 62a and 63a on the side operated by the switching mechanism 131 are formed of metal, and the mating gears 62ba and 63b are formed of resin. In addition, the combination of the gears made of resin and the friction can be reduced to make smooth rotation and weight reduction, and the lack of strength on the gears 62a and 63a side when the shifter 137 or the like is used for the switching mechanism 131, It is possible to prevent the seedling feeding case 59 from being enlarged by keeping the gears 62 and 63 in a small shape.

  Furthermore, in the said embodiment, in the rice transplanter which provided the traveling vehicle 1 which mounted the engine 2, and the planting part 15 provided with the seedling mounting stand 16 and the seedling planting nail | claw 17, the left-right inclination of the said planting part 15 is adjusted. A hydraulic rolling cylinder 99 serving as a rolling control device, and a seedling feeding case 59 for driving the seedling feeding shaft 58 of the seedling mounting table 16. The hydraulic rolling cylinder 99 causes the planting part 15 to rotate around the rolling fulcrum shaft 97. The hydraulic rolling cylinder 99 is arranged on one side of the planting part 15 and the other side of the planting part 15 around the rolling fulcrum shaft 97. Since the seedling feeding case 59 is distributed and arranged, the hydraulic rolling cylinder 99 and the seedling feeding case 59 are assembled in the planting part 15 with a good left-right balance, and Balance is considered good together with to enable stable traveling can be improved planting accuracy.

  The left and right side frames 23 for supporting the seedling table 16 are provided, and the left and right side frames 23 are provided on both the left and right sides of the hitch bracket 24. The hitch bracket 24 on which the rolling fulcrum shaft 97 is disposed and one of the hitch brackets 24 are provided. A hydraulic rolling cylinder 99 is disposed between the side frame 23 and connects the upper end side of the one side frame 23 and the lower end side of the hitch bracket 14 with a stay 110, while the outer side of the other side frame 23 is outside. The seedling feeding case 59 is arranged, and a planting depth adjusting lever 73 as a planting depth adjusting member for adjusting the seedling planting depth is arranged between the other side frame 23 and the hitch bracket 24. Therefore, the rigidity of the right side frame 23 is improved while being a lightweight structure that is connected by the stay 11, Performance can be secured.

DESCRIPTION OF SYMBOLS 1 Traveling vehicle 2 Engine 15 Planting part 16 Seedling stand 17 Seedling claw 20 Planting frame 58 Seedling feed shaft 59 Seedling feed case 97 Rolling fulcrum shaft 99 Rolling control device

Claims (2)

In a rice transplanter provided with a traveling vehicle equipped with an engine, and a planting part equipped with a seedling stand and a seedling planting claw,
A rolling control device that adjusts the right and left tilt of the planting part and a seedling feeding case that drives a seedling feeding shaft of the seedling stage, and the planting part is rotated around a rolling fulcrum axis by the rolling control device. And configured to tilt left and right,
A rice transplanter characterized in that the rolling control device is arranged on one side of the planting part and the seedling feeding case is distributed on the other side of the planting part around the rolling fulcrum shaft. The left and right side frames that support the seedling stage are provided, and the left and right side frames are provided on the left and right sides of the hitch bracket,
A rolling control device is arranged between the hitch bracket on which the rolling fulcrum shaft is arranged and one side frame, and connects the upper end side of the one side frame and the lower end side of the hitch bracket with a stay, while the other side The seedling feeding case is arranged outside the side frame, and a planting depth adjusting member for adjusting the planting depth of the seedling is arranged between the other side frame and the hitch bracket. Item 1. Rice transplanter according to item 1.

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