JP2010081945A - Levee-plastering machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a levee-plastering machine effectively performing an appropriate levee-plastering operation by smoothly sending soil for levee-plastering from each plowing claw to rearward levee-plastering component. <P>SOLUTION: The levee-plastering machine 1 plows and throws up soil for plastering the levee with a plurality of rows of plowing claws 96 projected from circumference surface of a rotary output axis 91 to the axis direction of the rotary output axis 91 at spaces to plaster the soil on an old levee with a levee-plastering component 105, while traveling along a levee by the travel of a tractor T. Wherein each tip bending part of the plurality of rows of plowing claws 96 is mounted to direct to the rearward levee-plastering component 105. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a hull coater that performs a hull painting operation while moving along a wrinkle during traveling of a traveling vehicle.

  Conventionally, for example, this type of coater moves along the fence based on the traveling of a traveling vehicle such as a tractor, and at a predetermined interval from the outer peripheral surface of the rotary shaft in the front-rear direction to the axial direction of the rotary shaft. A structure is adopted in which the soil for plowing is plowed and raised with a plurality of rows of tilling claws protruding in the state, and the raised soil is applied to the old paddle with a plowed body.

  The plurality of rows of tilling claws protruding from the rotating shaft that is driven to rotate are configured such that the protruding lengths from the rotating shaft are equal and the rotation locus is substantially cylindrical. Moreover, the paddy machine described in Patent Document 1 includes a plurality of rows of tilling claws arranged in the front-rear direction, and the rear tilling claws of the plurality of rows of tilling claws have a plate-like portion facing the rotation direction. ing.

JP 2001-28903 A (FIG. 2)

  In addition, regarding such a padding machine, there is a demand for a padding machine that can smoothly feed padding soil from each tilling claw toward the back padding body, and thus can perform appropriate padding work efficiently. ing.

  The present invention has been made in view of the above points, and can smoothly feed the soil for padding from each tilling claw toward the back padding body, so that an appropriate padding operation can be efficiently performed. An object of the present invention is to provide a coater that can be used.

  The spreader according to claim 1 is a plurality of protrusions that protrude along the axial direction of the rotary shaft from the outer peripheral surface of the rotary shaft in the front-rear direction while moving along the basket during traveling of the traveling vehicle. In the paddle coater that cultivates the soil for culling with the cultivating claws of the row and rakes it up to the old culvert with the lacquered body, each of the cultivating claws of the plurality of rows has the bent side at the end on the back. It is attached so as to face the glazed body.

  According to a second aspect of the present invention, in the first aspect of the first aspect of the present invention, the rotation shaft is configured such that the rotation axis can be adjusted about the rotation center axis in the left-right direction.

  The brush coater according to claim 3 is the brush coater according to claim 1 or 2, wherein the rotation shaft is configured to be adjustable with respect to the rotation center axis in the vertical direction together with the brush coating body. is there.

  According to a fourth aspect of the present invention, the tiller claw can be attached to and detached from the nail attachment portion provided on the outer peripheral surface of the output shaft and the nail attachment portion. The nail body is composed of a main body part and a bent part connected to the tip of the main body part so as to form a substantially L shape in plan view. It is what.

  According to the present invention, since the plurality of rows of tilling claws are attached so that the bent side of the tip faces the rearward hull, the soil for hulling is smoothly fed from each tillage nail toward the rear hull. Therefore, it is possible to efficiently and appropriately perform the smearing operation.

[BRIEF DESCRIPTION OF THE DRAWINGS] It is a top view of one Embodiment of the plastering machine of this invention. It is a top view at the time of the non-working of the same plastering machine. It is a top view at the time of the reverse operation | work of a same plastering machine. It is a side view of a drape coater same as the above. FIG. It is sectional drawing of the transmission means of a drape coater same as the above. It is a figure which shows the state after rotating and adjusting the rotation axis | shaft for the tilling nail | claw of a garnishing machine same as the above to the rotation center axis line of an up-down direction. It is a figure which shows the state after rotating and adjusting the rotation axis | shaft for the tilling nail | claw of a lid coating machine same as the above to the rotation center axis line of the left-right direction.

  Hereinafter, the configuration of an embodiment of a plastering machine according to the present invention will be described with reference to the drawings.

  In FIG. 1 to FIG. 5, reference numeral 1 denotes a tow-type coater, which is detachably attached to a tractor T as a traveling vehicle, and moves along the kite as the tractor T travels. However, it is intended to perform the lacquering operation.

  Note that, basically, the wiping machine 1 performs the wiping work while moving forward along the hoe based on the forward travel of the tractor T in the state set in the forward work state shown in FIG. At the end positions of the fields such as rice fields and fields, the padding operation is performed while moving backward along the ridges based on the backward movement of the tractor T in the state set in the backward operation state shown in FIG.

  As shown in FIGS. 1, 4 and 5, the coater 1 includes a tractor side frame 2 which is a fixed machine frame attached to the rear end portion of the tractor T. , It is arranged at the front side position, which is the side facing the tractor T of the coater 1.

  The tractor side frame 2 has a substantially box-shaped base portion 3 whose rear surface is opened rearward. The base portion 3 has a three-point connecting portion 4 as a tractor connecting portion connected to a three-point link mechanism T1 (three-point hitch type) as a work machine connecting portion provided at the rear end portion of the tractor T. It protrudes toward. The three-point connecting portion 4 includes, for example, a top mast 6 having a top pin 5 and a pair of left and right lower arms 8 and 8 having a lower pin 7.

  In addition, an input shaft 12 that is rotatably supported by a bearing portion 11 is provided at the lower central portion of the base portion 3 so as to protrude forward. A PTO shaft (not shown) of the tractor T is connected to the distal end side of the input shaft 12 via a universal joint, and power that can be expanded and contracted in the axial direction is connected to the proximal end side of the input shaft 12. One end side of the shaft main body member 13c of the transmission shaft body 13 is coupled via a coupling member 13a. As shown in FIG. 5, a protective cover 14 is attached to the outer peripheral side of the power transmission shaft body 13. The protective cover 14 is restricted in rotation by a chain (not shown) so as not to rotate together with the power transmission shaft body 13.

  Furthermore, a first support shaft body 15 as an arm connecting portion whose axial direction coincides with the vertical direction is provided at the center position in the left-right direction at the upper portion of the base portion 3.

  The first support shaft body 15 is fixed to the base portion 3 so as to straddle between the upper plate portion 16 and the intermediate plate portion 17 which are spaced apart from each other and are arranged perpendicular to the input shaft 12. Yes. As shown in FIG. 1, the input shaft 12 and the first support shaft body 15 are respectively located on the left-right direction center line X that is a line connecting the centers of the lengths of the tractor T in the left-right direction when viewed from the plane. Always located at.

  In addition, one side plate portion 19 of the pair of left and right rectangular side plate portions 18, 19 of the base portion 3, that is, the right side plate portion 19, has a widthwise dimension that is the front-rear direction of the coater 1. Compared to the side plate portion 18, the dimensions are shorter. Further, pin holding plates 21 and 21 as a pair of upper and lower pin holders spaced apart from each other are fixed horizontally on a surface of the right side plate portion 19 facing the left side plate portion 18.

  Each pin holding plate 21 is formed in an elongated rectangular plate shape having a longitudinal direction in the front-rear direction of the coater 1, and one end portion in the longitudinal direction is located behind the rear end position of the left side plate portion 18, and the upper plate It protrudes rearward of the coater 1 from the rear end position of the part 16 and the intermediate plate part 17. A pin insertion hole 22 penetrating vertically is formed at one end of each pin holding plate 21 protruding from the base portion 3.

  Further, the plastering machine 1 is provided with a first connecting arm body 23 having an elongated shape, and a base end portion which is one end portion in the longitudinal direction of the first connecting arm body 23 is connected to the tractor side frame 2. The first connecting arm body 23 is connected by a line passing through the axis of the first supporting shaft body 15, that is, the first supporting shaft body 15. The rotation is adjustable around a certain vertical rotation axis Y1. Note that the first connecting arm body 23 is formed by only one arm-forming member 24 having a square cylindrical shape formed in a straight line in the longitudinal direction without being bent in the middle in the longitudinal direction, for example.

  At the base end of the first connecting arm body 23, a first connecting portion 25a having an elongated cylindrical shape opened up and down is formed, and the first support shaft body 15 is formed in the first connecting portion 25a. It is inserted. In addition, an elongated cylindrical second connecting portion 25b having the same shape as that of the first connecting portion 25a and having an upper and lower opening is formed at the distal end which is the other end portion in the longitudinal direction of the first connecting arm body 23. Has been.

  Further, a connecting shaft portion 26 whose axial direction coincides with the vertical direction is formed on the lower surface of the central portion in the longitudinal direction of the first connecting arm body 23 so as to protrude downward.

  The connecting shaft portion 26 is provided with an elongated plate-shaped first fixing for restricting the rotation of the first connecting arm body 23 and fixing the first connecting arm body 23 to the tractor side frame 2. One end of the body 27 in the longitudinal direction is connected to be rotatable, and the first fixed body 27 is rotatable about the connecting shaft part 26 in the vertical direction. A plurality of, for example, three first holes 28a, 28b, and 28c for offset adjustment penetrating the upper and lower surfaces are adjacent to each other at a predetermined interval in the longitudinal direction at the central portion in the longitudinal direction of the first fixed body 27. It is formed in a state. Further, one second hole 29 penetrating the upper and lower surfaces is formed at the other end of the first fixed body 27 in the longitudinal direction.

  Furthermore, from a substantially central position in the longitudinal direction on one side surface (the right side surface in FIG. 1) along the longitudinal direction of the first connecting arm body 23, a pair of pin holding bodies that are spaced apart from each other vertically. The side pin holding plate portions 31 and 31 protrude horizontally in the lateral direction, and each one side pin holding plate portion 31 is formed with a pin insertion hole 32 penetrating vertically.

  Also, a pair of pin holders that are spaced apart from each other in the vertical direction from a position closer to the tip side than the center in the longitudinal direction on the other side surface (the left side surface in FIG. 1) along the longitudinal direction of the first connecting arm body 23. The other side pin holding plate portions 33, 33 project horizontally to the side, and each other side pin holding plate portion 33 is formed with a pin insertion hole 34 penetrating vertically. The one side pin holding plate part 31 and the other side pin holding plate part 33 are formed in the same shape. As shown in FIG. 4, the first connecting arm body 23 is disposed so as to have a front, rear, and lower slope that gradually slopes downward from the proximal end on the tractor side frame 2 side toward the distal end. Has been.

  Furthermore, the plastering machine 1 is provided with an elongated second connecting arm body 35, and a base end portion which is one end portion in the longitudinal direction of the second connecting arm body 35 is the first connecting arm body. It is connected to the tip part of 23 via the 2nd spindle 38 of an up-down direction so that rotation is possible. The second connecting arm body 35 is configured to be adjustable with respect to a rotation center axis Y2, which is a line passing through the axis of the second support shaft body 38, that is, the second support shaft body 38. Yes.

  The second connecting arm body 35 is constituted by, for example, a single elongated rectangular tubular arm member 36, a connecting member 37 having a U-shaped cross section fixed to one end of the arm member 36, and the like. ing.

  The connecting member 37 has an upper plate portion 37b and a lower plate portion 37c which are connected to each other by a mounting plate portion 37a along the vertical plane and which are spaced apart from each other in the vertical direction. The upper plate portion 37b and the lower plate portion 37c The second support shaft 38 is supported, and the axial direction of the second support shaft 38 coincides with the vertical direction. The second support shaft 38 is arranged in parallel with the first support shaft 15. Has been. Further, as shown in FIG. 5, the second support shaft body 38 is inserted into the second connection portion 25 b at the distal end portion of the first connection arm body 23.

  On the other hand, the arm member 36 has one end portion in the longitudinal direction fixed to the mounting plate portion 37a of the connecting member 37, and a connecting shaft portion 48 whose axial direction coincides with the vertical direction is directed upward on the upper surface near the center in the longitudinal direction. It is formed in a protruding state.

  The connecting shaft portion 48 has a long and narrow plate-like shape for restricting the rotation of the second connecting arm body 35 and fixing the second connecting arm body 35 to the first connecting arm body 23. One end portion in the longitudinal direction of the second fixed body 39 is rotatably connected, and the second fixed body 39 is rotatable around the connecting shaft portion 48 in the vertical direction. An insertion hole 40 penetrating the upper and lower surfaces is formed at the other end of the second fixed body 39 in the longitudinal direction.

  In the forward working state shown in FIG. 1 of the coater 1, for example, the first hole 28b of the first fixed body 27 and the pin insertion hole 22 of the pin holding plate 21 of the tractor side frame 2 are aligned vertically. The first operation pin 43 as the operation body is inserted and attached to the first hole 28b and the pin insertion hole 22 that coincide with each other, and the insertion hole 40 of the second fixed body 39 and the first connecting arm body 23 are inserted. The pin insertion hole 32 of the one-side pin holding plate portion 31 is aligned vertically, and a second operation pin 44 as an operation body is inserted and attached to the corresponding insertion hole 40 and the pin insertion hole 32. .

  Thus, the first connecting arm body 23 and the second connecting arm body 35 are fixed to the tractor side frame 2, and the second connecting arm body 35 is the rear end of the first connecting arm body 23. It is in the state which protruded from the part toward the right side. In this state, the rotation center axis Y2 of the second connecting arm body 35 is not located on the left-right direction center line X of the tractor T, and the right side that is one side of the tractor T from the left-right direction center line X. At a position shifted by a predetermined distance. Further, the second connecting arm body 35 is located in a state where the longitudinal direction of the second connecting arm body 35 substantially coincides with the horizontal direction of the spreader 1.

  Further, as shown in FIG. 2, only the first operation pin 43 is once extracted from the forward operation state of FIG. 1, and the first connection arm body 23 is moved to the second connection arm body about the rotation center axis Y1. 35, the second hole 29 of the first fixed body 27 and the pin insertion hole 22 of the pin holding plate 21 of the tractor side frame 2 are vertically aligned with each other. When the first operation pin 43 is inserted and reattached to the pin 29 and the pin insertion hole 22, the first connection arm body 23 and the second connection arm body 35 are fixed to the tractor side frame 2. The coating machine 1 is set to the non-working state located at the rear position of the tractor T. In this state, the rotation center axis Y2 of the second connecting arm body 35 is not located on the left-right direction center line X of the tractor T, and the left side which is the other side of the tractor T from the left-right direction center line X. At a position shifted by a predetermined distance.

  Further, as shown in FIG. 3, from the non-working state of FIG. 2, only the second operation pin 44 is once extracted, and the second connecting arm body 35 is rotated while the first connecting arm body 23 is fixed. Rotate a predetermined amount around the movement center axis Y2, and vertically move the insertion hole 40 of the second fixed body 39 and the pin insertion hole 34 of the other side pin holding plate portion 33 of the first connecting arm body 23. When the second operation pin 44 is inserted and reattached to the insertion hole 40 and the pin insertion hole 34, the first connection arm body 23 and the second connection arm body 35 are connected to the tractor. It is fixed with respect to the side frame 2, and the coater 1 is set in a reverse operation state in which the coater 1 can be applied based on the backward travel of the tractor T.

  In this state, the rotation center axis Y2 of the second connecting arm body 35 is not located on the left-right direction center line X of the tractor T, and the left side which is the other side of the tractor T from the left-right direction center line X. At a position shifted by a predetermined distance. Further, the second connecting arm body 35 is located in a state where the longitudinal direction of the second connecting arm body 35 substantially coincides with the horizontal direction of the spreader 1.

  On the other hand, as shown in FIGS. 1, 4 and 5, the plastering machine 1 is provided with a work side frame 51 which is a moving machine frame attached to the distal end portion of the second connecting arm body 35. The earth work means 45 is supported by the side frame 51 in a suspended state.

  The working side frame 51 includes an adjusting body mounting member 57 including two plate portions 56 and 56 projecting from the upper surface of the other end portion in the longitudinal direction of the arm member 36 of the second connecting arm body 35, and the length of the arm member 36. And a supporting body attaching member 58 having a U-shaped cross section protruding from the lower surface of the other end portion in the direction.

  Then, a base end portion, which is one end portion in the longitudinal direction of the adjustment body 60 for adjusting the working depth formed in an elongated plate shape, is provided on the plate portion 56 of the adjustment body attaching member 57 via a pin 61 in the horizontal direction. And is pivotally attached. The adjusting body 60 is rotatable about the pin 61 so that the tip end is raised and lowered, and a plurality of, for example, three adjusting holes 62a, 62b, 62c penetrating left and right are formed at the tip. Yes. These three adjustment holes 62a, 62b, and 62c are juxtaposed to each other at a predetermined interval in the longitudinal direction of the adjustment body 60 at the distal end portion of the adjustment body 60.

  In addition, a horizontal shaft 65 is horizontally spanned between the plate portions 58a and 58b that are spaced apart from each other on the left and right sides of the shaft mounting member 58, and the axial direction of the shaft 65 is the horizontal direction. It matches. A base end portion of an elongated support arm 66 having a longitudinal direction in the front-rear direction is rotatably attached to the support shaft body 65.

  The support arm 66 is configured to be rotatable about a rotation center axis A that is a line passing through the shaft center of the support shaft body 65, that is, the support shaft body 65 so that the tip end side is raised and lowered. A pair of plate-shaped pin holding portions 67, 67 that are spaced apart from each other and protrude from the upper surface in the vicinity of the distal end portion of the arm 66 project, and each pin holding portion 67 is formed with a pin insertion hole 68 that penetrates left and right. Yes.

  For example, in the state shown in FIG. 4, the pin insertion hole 68 of the support arm 66 and the selected adjustment hole 62b, for example, coincide with each other, and the matching adjustment hole 62b and the pin insertion hole 68 are operated. The adjustment pin 69 as a body is inserted and attached, and as a result, the support arm 66 is fixed to the support shaft body 65 so as not to rotate. In this state, the longitudinal direction of the support arm 66 coincides with the front-rear horizontal direction of the coater 1.

  Further, as shown in FIG. 4, the work side frame 51 has a single transmission case 72 fixed to the support arm 66 via attachment members 71, 71.

  The single transmission case 72 has a function of a support frame for supporting the earth working means 45, and has a hollow input shaft support portion 74 as shown in FIG.

  Then, a substantially rotary cylindrical hollow support portion 75 projects forward from the front surface portion which is one side surface portion of the input shaft support portion 74, and is the other side surface portion of the input shaft support portion 74. A hollow plaster support portion 76 projects rearward from the rear surface portion.

  This input shaft support portion 74 supports a horizontal intermediate input shaft 82 in a horizontal manner so as to be rotatable via a plurality of bearing members 81, and the front end side of this intermediate input shaft 82 is an input shaft support. Through the circular insertion port 74a formed in the left side surface which is one side surface of the portion 74, it protrudes outside the input shaft support portion 74 and is exposed.

  The other end portion of the shaft main body member 13c of the power transmission shaft body 13 whose one end portion is connected to the input shaft 12 via the connecting member 13a is attached to the tip end portion of the intermediate input shaft 82 that protrudes outside the input shaft support portion 74. Are connected via a connecting member 13b. Each of the connecting member 13a and the connecting member 13b is, for example, a double wide-angle universal joint, and the power transmission shaft body 13 is configured by the connecting member 13a, the connecting member 13b, the shaft main body member 13c, and the like. As shown in FIG. 1, the axial direction of the intermediate input shaft 82 is substantially coincident with the horizontal direction of the coater 1 and is orthogonal to the axial direction of the input shaft 12 when viewed from the plane.

  A first bevel gear 83 and a first gear 84 are fixed to the base end portion accommodated in the input shaft support portion 74 of the intermediate input shaft 82 in the axial direction.

  The first bevel gear 83 of the intermediate input shaft 82 is engaged with the second bevel gear 87 of the intermediate connecting shaft 86 rotatably supported by a plurality of bearing members 85, and the second bevel gear 87 of the intermediate connecting shaft 86 is engaged. The gear 88 meshes with a third gear 92 of a rotary output shaft 91 as a rotation shaft in the front-rear direction. The first bevel gear 83, the second bevel gear 87, the first gear 84, the second gear 88, the third gear 92, and the intermediate connecting shaft 86 are accommodated in the input shaft support portion 74.

  The rotary output shaft 91 is supported by a rotary support portion 75 in a state in which the axial direction coincides with the front-rear direction. The rotary output shaft 91 is connected to one of the bearing members 93 in the input shaft support portion 74 and a rotary shaft. It is rotatably supported by the other bearing member 94 in the support portion 75 for use.

  Further, a plurality of rows of tillage are cultivated on the outer peripheral surface of the front end portion, which is a tip portion projecting through the insertion port 75a outside the rotary support portion 75 of the rotary output shaft 91, and the soil for plowing is plowed up. A claw 96 is projected.

  That is, on the outer peripheral surface of the front end portion of the rotary output shaft 91, for example, a plurality of elongated claw mounting portions 95, 95 protruding in two different directions are arranged in a plurality of rows at equal intervals in the axial direction of the rotary output shaft 91. For example, three rows are juxtaposed, and the lengths of the three rows of claw mounting portions 95 are shorter toward the front side of the rotary output shaft 91. That is, the protruding length of the front claw mounting portion 95 is sequentially shorter than the protruding length of the rear claw mounting portion 95.

  In addition, a claw body 97 having the same predetermined shape and the same length is detachably attached to the tip of each claw attachment portion 95. Each claw body 97 has a main body portion 97a and a bent portion 97b connected to the front end of the main body portion 97a so that the front end side is bent rearward, that is, in a substantially L shape in plan view. It is composed of. The length of the bent portion 97b is substantially equal to the distance between the claw attaching portions 95 and 95 adjacent to each other in the front and rear, and the rear end of the bent portion 97b is located in the vicinity of the main body portion 97a one rear.

  Further, the nail attachment portion 95 and the nail body 97 constitute a tilling claw 96 having a step, and these multiple rows, for example, three rows of tilling claws 96 are arranged in the axial direction from the outer peripheral surface of the rotary output shaft 91 in the front-rear direction. Protrusions with equal intervals.

  Further, these three rows of tilling claws 96 are formed in a step shape so that the protrusion length H from the rotary output shaft 91 becomes shorter toward the front side in the traveling direction, and the rotation trajectory has a substantially truncated cone shape with a step. .

  That is, the protruding length H of the tilling claw 96 on the front side of the traveling direction from the rotary output shaft 91 is successively shorter than the protruding length of the tilling claw 96 on the rear side of the traveling direction, and the first row of the front end position of the rotary output shaft 91 The protruding length H = H2 of the second row of claws 96 is longer than the protruding length H = H2 of the second row of claws 96, and the third row of the protruding length H = H2 of the second row of claws 96 The protruding length H = H3 of the tilling claw 96 is longer.

  In FIG. 6, the tilling claws 96 in each row are shown in the same phase, but the second row tilling claws 96 are out of phase by 60 degrees with respect to the first row tilling claws 96. 96 is 60 degrees out of phase with the second row of claws 96. A rotary 98 is constituted by these three rows of tilling claws 96.

  Then, the rotary 98 is driven and rotated integrally with the rotary output shaft 91 by the driving force from the tractor T, and the plowing soil is cultivated, crushed and lifted up. The upper side and the side of the rotary 98 are covered with a cover body 99 that prevents the scattering of soil as shown in FIG.

  On the other hand, the fourth gear 102 of the smeared body output shaft 101 is engaged with the first gear 84 of the intermediate input shaft 82 supported by the input shaft support portion 74. The smeared body output shaft 101 is supported by the smeared body support portion 76 in a state where the axial direction coincides with the left and right horizontal directions. Are rotatably supported by a plurality of bearing members 100.

  In addition, the half-finished body output shaft 101 is housed in the half-coated body support portion 76 at the base end side, and the half on the front end side protrudes outside the half-coated body support portion 76 through the insertion port 76a. The axial direction of the smeared body output shaft 101 and the axial direction of the rotary output shaft 91 are arranged so as to be orthogonal in a plan view. In the state shown in FIGS. 4 and 5, the rotation center axis A is positioned in the vicinity of the rotation center axis B in the left-right horizontal direction, which is a line passing through the axis of the hulled body output shaft 101, It is substantially parallel to the rotation center axis B and substantially coincides with the rotation center axis A and the rotation center axis B in plan view.

  Then, a substantially cylindrical glazing body 105 is attached to a tip end portion of the glazing body output shaft 101 protruding outside the glazing body support portion 76 via a frustoconical annular member 104.

  The corrugated body 105 includes, for example, a cylindrical upper surface coating member 106 that trims the upper surface portion of the old paddle, and a frustoconical side surface coating member 107 that trims the inclined side surface portion of the old paddle. It is composed of. The upper part of the glazed body 105 is covered with a cover body 108 that prevents scattering of soil. Note that the earthen work body 45 is constituted by the plaster body 105 and the rotary 98.

  Thus, as shown in FIG. 1, the rotary 98 is attached to the single transmission case 72 of the work side frame 51 via the rotary output shaft 91 in the front-rear direction, and the hull 105 is output in the left-right hull It is attached via a shaft 101.

  Here, the rotary output shaft 91 is rotated and adjusted in the left-right direction around the rotation center axis Y1 in the vertical direction together with the hull body 105 so that the front wheels and wheels of the tractor T can follow the old hail. It is possible. That is, the first connecting arm body 23 is rotated around the first support shaft body 15 and the first holes 28a, 28b, and 28c through which the first operation pin 43 is inserted are switched, whereby the rotary output shaft 91 is switched. Can be rotated in the left-right direction.

  Further, the rotary output shaft 91 can be adjusted to rotate about the rotation center axis A in the left-right direction so that the working depth of the rotary 98 can be set to a desired depth, that is, the support arm 66. The rotary output shaft 91 is moved up and down by rotating the adjusting body 60 about the pin 61 and rotating the adjusting body 60 about the pin 61 and switching the adjusting holes 62a, 62b and 62c through which the adjusting pin 69 is inserted. It can be rotated in the direction.

  Then, after the earth working means 45 has adjusted to a desired state, when the driving force from the tractor T side is input to the intermediate input shaft 82 via the input shaft 12, the power transmission shaft body 13, etc., the rotary output The shaft 91 is driven to rotate in a predetermined direction, and the smeared body output shaft 101 is driven to rotate in a predetermined direction. As a result, the nail body 97 of the rotary 98 cultivates the soil for plowing and splashes it up, and this soil is applied to the top surface of the old paddle by the top surface coating member 106 of the surface coating body 105. A member 107 is applied to the side surface of the old bag to form a new bag. The rotational speed of the haze 105 is set to be faster than the wheel rotational speed of the tractor T.

  On the other hand, as shown in FIGS. 4 and 5, the coater 1 prevents the rotary 98 and the coat 105 from being lifted off the kite by the force received from the soil in the field. 111.

  The lifting prevention means 111 includes an elongated plate-like support body 113 having a longitudinal direction in the vertical direction fixedly attached to the support arm 66 and the rotary support portion 75 of the single transmission case 72 via the attachment member 112. The soil traveling body 115 is integrally provided at the lower end of the support body 113 and can travel in the soil of the farm field.

  The soil traveling body 115 includes, for example, a side surface coating member pressing portion 117 that presses the side surface coating member 107 of the surface coating body 105 against the side surface portion of the old surface, and an upper surface coating member 106 of the surface surface coating body 105. And an upper surface coating member pressing portion 116 to be pressed to the portion.

  The side surface coating member pressing portion 117 is formed, for example, in the shape of an elongated plate having a longitudinal direction in the vertical direction, and is arranged in an inclined shape as shown in FIG. That is, the side coating member pressing portion 117 has a distance from the lateral center line X of the tractor T from one end side in the width direction to the other end side, that is, from the rear end side to the front end side in the traveling direction. It is inclined to gradually increase. As shown in FIG. 4, a cutting blade portion 117a that cuts the ground surface vertically is formed at the front end edge of the side surface coating member pressing portion 117 in the traveling direction.

  The upper surface coating member pressing portion 116 is formed in a substantially square plate shape, and is fixed to the lower end portion of the side surface coating member pressing portion 117 in an inclined manner as shown in FIG. That is, the upper surface coating member pressing portion 116 is inclined downward from the rear end side in the traveling direction toward the front end side, and the front end side in the traveling direction is formed in a tapered shape.

  Then, during traveling of the underground traveling body 115 based on traveling of the tractor T, earth pressure acts on one side surface of the side coating member pressing portion 117 facing the front in the traveling direction, and as a result, the side coating member 107 is aligned in the traveling direction. The outer side of the side surface coating member 107 is pressed against the inclined side surface portion of the old bag with a relatively strong pressing force. At the same time, earth pressure acts on the upper surface of the upper surface coating member pressing portion 116. As a result, the upper surface coating member 106 is biased downward, and the lower surface side of the upper surface coating member 106 is applied with a relatively strong pressing force to the upper surface portion of the old iron. Pressed down. For this reason, a tightly-tightened ridge is formed by the glazed body 105.

  The input shaft 12, the power transmission shaft body 13, the connecting members 13a and 13b, the intermediate input shaft 82, the first bevel gear 83, the second bevel gear 87, the intermediate connecting shaft 86, the second gear 88, the third gear 92, The rotary output shaft 91, the first gear 84, the fourth gear 102, and the smeared body output shaft 101 constitute a transmission means 110. This transmission means 110 transmits the power from the tractor T side to the rotary 98 and the smeared body 105. Is transmitted to the soil working means 45.

  Next, the case where the glazing operation | work which repairs an old candy is performed using the said one Embodiment is demonstrated.

  When performing the drape work, which is a soil work, the operator uses the three-point link mechanism T1 of the tractor T to lift the entire drape coater 1 to a predetermined height position and hold it in a suspended state. The operation pin 43 and the second operation pin 44 are appropriately operated to set the wrinkle coater 1 to the forward operation state shown in FIG.

  In the forward operation state of FIG. 1, the rotary 98 and the hulling body 105 are arranged on the right side which is one side of the hulling machine 1 and slightly protrude to the right side from the tractor T, and the rotary 98 is located on the tractor T side. Then, the brushed body 105 is located behind the rotary 98.

  Here, for example, due to the size of the tractor T, for example, the tread which is the width of the left and right wheels, in the state shown in FIG. 1, that is, the state shown by the two-dot chain line in FIG. If the lower end portion cannot be aligned, as shown by the solid line in FIG. 7, the rotary output shaft 91 is turned around the rotation center axis Y1 by switching the first operation pin 43 to the first hole 28c. The rotation is adjusted, and the rotary output shaft 91 is slightly inclined with respect to the front-rear direction so as to approach the old shaft side toward the front end.

  In addition, with the rotation of the rotary output shaft 91, the glazing body 105 rotates and is slightly displaced in the left-right direction center line X side. Although not shown, when the first operation pin 43 is switched to the first hole 28a, the rotary output shaft 91 is slightly inclined with respect to the front-rear direction so as to be farther from the old shaft side toward the front end.

  Further, for example, in the state indicated by the two-dot chain line in FIG. 8, if the amount of soil supplied to the old fence side is not sufficient, the adjustment pin 69 is adjusted as indicated by the solid line in FIG. By switching to the use hole 62a, the rotary output shaft 91 is rotated and adjusted around the rotation center axis A, and the rotary output shaft 91 is inclined in a front, rear, and rear height so as to approach the front surface side toward the front end. The lower end of the rotary 98 is positioned within the rice field c. Although not shown, when the adjustment pin 69 is switched to the adjustment hole 62c, the rotary output shaft 91 is inclined so as to be front and rear and low.

  In this way, after the rotary 98 and the glazed body 105 are arranged at appropriate work positions, the lifting and holding of the tractor T by the three-point link mechanism T1 is released, and the tractor T is moved along the tractor T while keeping the wheels of the tractor T along the old rod When traveling forward, the lacquer T moves together with the tractor T along the old tub.

  By the movement of the paddle coater 1, the paddy soil is cultivated and spun up by the rotary 98, and the desired amount of the sprinkled soil is applied to the old paddle by the paddle body 105. Are arranged to form a new newspaper. It should be noted that the three rows of tilling claws 96 constituting the rotary 98 are cultivated so as to dig up the soil on the surface of the rice field and the soil on the side surface of the old paddle.

  The operator in the driver's seat can obtain the straight traveling performance of the tractor T by moving the wheels of the tractor T along the old fence, and the tractor T can travel straight in the traveling direction.

  In addition, during traveling of the paddle coater 1, the underground traveling body 115 of the lifting prevention means 111 travels in the soil of the table surface, and earth pressure in a predetermined direction acts on the underground traveling body 115. As a result, the weight of the coater 1 is increased by that amount, and the side coating member 107 of the coater 105 is pressed against the inclined side surface portion of the old kite with a relatively strong pressing force. The upper surface coating member 106 is pressed against the upper surface of the old iron with a relatively strong pressing force to form a new tightly tightened iron.

  Then, when the formation of the new straw progresses and the tractor T reaches the end of the field, the operator at the driver's seat turns the handle of the tractor T and reverses the direction of the tractor T.

  Next, the operator once pulls out the first operation pin 43 in a state where the coater 1 is lifted and held at a predetermined height position using the three-point link mechanism T1 of the tractor T, and the first connecting arm The body 23 is rotated by a predetermined amount together with the second connecting arm body 35, the work side frame 51 and the like about the rotation center axis Y1, and the second hole 29 of the first fixed body 27 and the pin of the tractor side frame 2 are rotated. The pin insertion hole 22 of the holding plate 21 is made to be in a vertically aligned state, and the first operation pin 43 is inserted into the second hole 29 and the pin insertion hole 22 and reattached.

  Further, the operator pulls out the second operation pin 44 once and keeps the first connecting arm body 23 fixed, and then moves the second connecting arm body 35 around the rotation center axis Y2 to the work side frame 51 and the like. And a state where the insertion hole 40 of the second fixed body 39 and the pin insertion hole 34 of the other side pin holding plate portion 33 of the first connecting arm body 23 are vertically aligned with each other. The second operation pin 44 is inserted into the insertion hole 40 and the pin insertion hole 34 and reattached. The power transmission shaft body 13 of the transmission means 110 is connected to the input shaft 12 and the intermediate input shaft 82 when the rotation of the first connection arm body 23 and the rotation of the second connection arm body 35 are adjusted. It does not need to be disconnected.

  Thus, the rotary 98 and the hull body 105 of the hull coater 1 in the reverse operation state of FIG. 3 are arranged on the left side which is one side of the hull coater 1, and protrudes to the left with respect to the tractor T. The glazed body 105 is located on the tractor T side, and the rotary 98 is located behind the glazed body 105. In this state, the rotary 98 and the brushed body 105 are set so that the protruding amount (distance from the left and right center line X of the tractor T) is larger than that in the forward working posture of FIG. Has been.

  Then, after releasing the lifting and holding by the three-point link mechanism T1 of the tractor T, the worker causes the tractor T to travel backward while maintaining the space between the wheels of the tractor T and the new roll.

  Then, the coater 1 moves together with the old tractor T together with the tractor T, and the paddy soil is cultivated and spun up by the rotary 98. Then, it is painted and arranged on the old wall, and a new wall is formed. At this time, the wheel of the tractor T does not crush the new roll, and the wheel does not fall into the concave groove formed in the paddle surface C by the rotary 98, so that the tractor T does not tilt.

  On the other hand, when the worker applies the padding machine 1 or removes the padding machine 1 from the tractor T, the worker uses the earth work means 45 including the rotary 98 and the padding body 105 as shown in FIG. Set to non-working state.

  That is, as shown in FIG. 2, the rotary 98 and the glazed body 105 are set in the rear position of the tractor T in a state where they are arranged in an inclined direction intersecting with the traveling direction of the tractor T.

  The rear position of the tractor T is, for example, that the center of gravity of the entire coater 1 is in the left and right direction behind the tractor T so that the right and left weight balance of the tractor T in a state where the coater 1 is lifted and held can be improved. A position located on the center line X or, for example, the center of the size in the left-right direction (width-direction size) of the coater 1 is reduced so that the protrusion to the side of the tractor T of the coater 1 can be reduced. It is a position located on the center line X in the left-and-right direction in the rear. Note that the rear position of the tractor T is such that the center of gravity of the entire coater 1 and the center of the horizontal dimension (width dimension) of the coater 1 are both positioned on the lateral centerline X behind the tractor T. It is more preferable if it is a position.

  According to the above-described embodiment, a plurality of rows of, for example, three rows of tilling claws 96 are stepped so that the protruding length H of the front tilling claws 96 is successively shorter than the protruding length H of the rear tilling claws 96. Since it is configured in the shape, it is possible to reliably distribute the tillage resistance at the time of work, to suppress the magnitude of the load from the soil acting on the tilling claws 96, 96, 96 of each row, and therefore, it is possible to relatively reduce the tillage vibration, Stable coating can be performed.

  Further, the rotary output shaft 91 is configured so as to be rotatable and adjustable around the vertical rotation center axis line Y1 together with the padding body 105. The coating body 105 can be arranged at an appropriate work position, and the tractor T can be moved forward while keeping the wheel along the lower end of the old paddle. Therefore, the tractor T does not fluctuate and can be appropriately padded. .

  Moreover, even if the rotary output shaft 91 is slightly inclined with respect to the front-rear direction so as to approach the heel side as it approaches the front end, the protrusion length from the rotary output shaft 91 is shorter as the three rows of tilling claws 96 become the front side. Therefore, only the first row of the tilling claws 96 does not go too far to the rod side, the tillage resistance can be appropriately distributed, and the tilling vibration can be surely reduced.

  Furthermore, since the rotary output shaft 91 is configured to be adjustable around the rotation center axis A in the left-right direction, for example, depending on the soil quality of the rice field, the amount of soil supplied to the old paddy side, etc. The working depth of the nail 96 can be set to a desired depth, and an appropriate wrinkling operation can be performed.

  Moreover, even if the rotary output shaft 91 is tilted so as to be high in front and back, the protrusion length from the rotary output shaft 91 becomes shorter as the three rows of tilling claws 96 become the front side. Only the working depth of the tilling claws 96 in the row does not become too deep, tilling resistance can be properly distributed, and tilling vibration can be reliably reduced.

  Furthermore, each of the bent tilling claws 96 is attached to the rotary output shaft 91 so that the bent end of each of the tilling claws 96 faces the rearward hull body 105. Can be smoothly fed from the front end side toward the rear smear body 105, so that an appropriate smearing operation can be performed efficiently.

  Further, since the tillage vibration can be reduced by dispersion of tillage resistance with respect to the tilling claw 96, the soil mass can be reduced, the crushed property of the tilling claw 96 can be improved, and a new tightly-tightened rice cake can be formed.

  In the above-described embodiment, the case where three rows of tilling claws 96 project from the outer peripheral surface of the front end portion of the rotary output shaft 91 has been described. However, the row is not limited to three rows, for example, two rows or four rows or more. It may be.

  In any of the above-described embodiments, each row of tilling claws 96 has two configurations facing two different directions, but is directed radially in many directions, such as four directions, five directions, and eight directions. Any number of configurations may be used.

  Further, the tilling claw 96 is not limited to one constituted by a claw mounting portion 95 having a different length and a claw body 97 having the same length. For example, although not shown, it is different from a claw mounting portion having the same length. It may be composed of a long nail body.

1 Spider coater
91 Rotary output shaft as rotating shaft
95 Claw mount
96 tillage claws
97 Nail body
97a Body
97b Folding part
105 Coated body T Tractor as a traveling vehicle A Left and right turn center axis Y1 Up and down turn center axis

Claims (4)

While moving along the fence during traveling of the traveling vehicle, the soil for padding with a plurality of rows of tilling claws protruding from the outer peripheral surface of the rotary shaft in the front-rear direction at a predetermined interval in the axial direction of the rotary shaft In a cocoon coater that coats the raised soil on the old cocoon with a cocoon coat,
The plurality of rows of tilling claws are each attached so that the bent side of the tip faces the rearward hulling body. The wrinkle coater according to claim 1, wherein the rotation shaft is configured to be capable of rotation adjustment about a rotation center axis in the left-right direction. The rotary coater according to claim 1 or 2, wherein the rotary shaft is configured to be capable of rotating and adjusting around a rotation center axis in the vertical direction together with the brushed body. The tilling nail is composed of a nail attachment portion provided on the outer peripheral surface of the output shaft and a nail body removably attached to the nail attachment portion.
The said nail | claw main body is comprised by the main-body part and the bending part provided in a row by the front-end | tip of this main-body part so that it may make a substantially L shape by planar view. 4. A coater according to any one of 3 above.

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