JPH1098907A - Ridging machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To miniaturize a structure and to provide a ridging machine suitable for establishment work or the like capable of forming a strong ridge without being affected by a soil property or weather or the like by providing a ridge side cover member with a soil amount adjustment mechanism movable and adjustable in the width direction of the ridge. SOLUTION: A machine frame is provided with a banking mechanism 4 for heaping up soil on an old ridge, a cover member 10 is disposed on the upper part and a ridging mechanism 12 capable of pressing and ridging banking is disposed on the rear part position in an advancing direction of the banking mechanism 4. The ridging mechanism 12 is composed of a rotary ridging body 13 capable of ridging one side face of the ridge W and the upper surface of the ridge W and the rotary axial line of the rotary ridging body 13 is arranged in the upward direction of a prescribed angle toward an oblique upper part from the side part of one side face of the ridge W to the side of the ridge W. The cover member 10 is composed of a machine frame side cover member 10a and a ridge side cover member 10b and the ridge side cover member 10b is provided with the soil amount adjustment mechanism T movable and adjustable in the width direction of the ridge W. Also, it is preferable to form a side part cover member 11 capable of being in slidable contact with the upper surface of the ridge W in the ridge side cover member 10b.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rowing machine used for, for example, ridge construction work or restoration work.

[0002]

2. Description of the Related Art Conventionally, as this kind of ridge setting machine,
1-1141212, JP-B-51-47785, JP-A-53-102411, and JP-A-53-2
No. 0316, Japanese Patent Application Laid-Open No. Sho 51-100409, Japanese Utility Model Application Laid-Open No. 60-119209, Japanese Utility Model Application Laid-Open No. 61-1759.
No. 05, JP-A-61-47103, JP-A-6-47103
1-2212202, Japanese Utility Model Application Laid-Open No. 62-1507, Japanese Utility Model Application Laid-Open No. 61-158105, Japanese Utility Model Application Laid-Open No. 3-79.
Japanese Patent Application Laid-Open No. 605-605 and Japanese Utility Model Application Laid-Open No. 5-60207 are known.

In these conventional structures, a machine frame is connected to a traveling machine body by a connecting mechanism so that the machine frame can be moved up and down, and a rotary rotor that jumps up the soil on an old ridge as a banking mechanism is connected to the machine frame by using a rotating axis of the ridge. Provided in a direction parallel or intersecting with the creation direction,
A cover member is provided above the rotating rotor and above the ridge on the machine frame, and a ridge body having a shape conforming to the upper surface of the ridge and one side of the ridge is provided at a position rearward in the traveling direction of the rotating rotor, and the power of the traveling body is provided. A crank-type or hydraulic-type striking mechanism for reciprocating striking of the ridges using the take-out shaft as a drive source is provided.The traveling machine is driven along the old ridges, and the mud in the field is raised on the old ridges by the rotating rotor. The embankment is struck by a ridge striking operation of the ridge.

[0004] In another conventional structure, a vibration mechanism for vibrating the ridge body using a power take-off shaft of a traveling machine as a drive source is provided as a ridge mechanism, and the embankment raised on the old ridge is provided. There is also a configuration in which the ridge is tightened by the vibration action of the ridge.

[0005]

However, in the case of the above-mentioned conventional structure, there is an inconvenience that it may not always be possible to perform satisfactory furrowing work depending on the working conditions such as the soil quality of the furrow which differs depending on the region and the weather. doing.

[0006]

The object of the present invention is to solve such inconveniences.
In the invention according to claim 1, the machine frame is connected to the traveling machine body by the connecting mechanism, an embankment mechanism for raising the soil on the old ridge is provided on the machine frame, and a cover member is provided above the embankment mechanism,
At the rearward position in the traveling direction of the embankment mechanism, an embankment mechanism capable of compacting and embedding the embankment is provided. The rotation axis of the rotating ridge body is arranged in an upward direction at a predetermined angle obliquely upward from the side of one side of the ridge to the ridge side, and the cover member includes a machine frame side cover member and a ridge side cover member. And a soil volume adjusting mechanism which is capable of adjusting the movement of the ridge side cover member in the width direction of the ridge.

The invention according to claim 2 is characterized in that the ridge side cover member is provided with a side cover member that can slide on the upper surface of the ridge. The invention described in the above is characterized in that the side cover member is slidably in contact with the upper surface of the ridge and is provided so as to be movable up and down in accordance with the ups and downs of the ridge. The above-mentioned rotating ridges consist of a lower rotating ridge that can ridge one side of the ridge and an upper rotating ridge that can ridge the upper surface of the ridge. On the other hand, it is characterized by being arranged in the upward direction at a predetermined angle from the side of the side surface to the ridge side diagonally upward, and the invention according to claim 5 is characterized in that the embankment mechanism is in the forward direction in the traveling direction. It is characterized by having a soil removal mechanism for removing the top surface of the old ridge at the position.

[0008]

1 to 11 show an embodiment of the present invention. FIGS. 1 to 8 show a first embodiment, and FIGS. 9 to 11 show a second embodiment.

In the first embodiment of the present invention shown in FIGS. 1 to 8, reference numeral 1 denotes a traveling body, in which a tractor is used, and a three-point link type connecting mechanism 2 is provided at the rear of the traveling body 1. The machine frame 3 is connected to be vertically movable.

Reference numeral 4 denotes an embankment mechanism, which in this case comprises a rotating rotor 5 having a rotating axis substantially parallel to the traveling direction.
The rotating rotor 5 has a plurality of saw blades 5b radially protruding from the outer periphery of a rotor body 5a. In this case, the saw blades 5b are positioned in three rows of front, middle, and rear rows in the front and rear direction of travel.
Three blades 5b are protruded at three equally spaced positions in the radial direction of the row, and a total of nine blades 5b are protruded, and each blade 5b in each row is a value obtained by dividing 360 degrees by nine. Are arranged so as to be shifted from each other in the circumferential direction at 40 degrees. Of these, a total of six saw blades 5b in the front row and the middle row in the advancing direction are crushed clay whose tip portions formed exclusively for crushing soil are straight or slightly twisted. The three knives 5b in the rear row formed in the blade E are formed in the jumping blade G whose tip end formed exclusively for jumping up onto the old ridge W is slightly twisted, and further in each row. The length from the rotation axis to the tip edge of the saw blade 5b is formed so as to gradually increase as it goes backward in the rotation direction. A mounting shaft 5c protrudes from the rotor body 5a. The rotating rotor 5 is rotatably mounted with its rotation axis substantially parallel to the ridge forming direction as the traveling direction, and is attached to the machine frame 3. Provided line body 1 power take-off shaft 6
And the rotating rotor 5 is supported by the main shaft 7.
The rotation is performed through the turning gear train 8 and the chain mechanism 9, and the rotation rotor 5 cuts out the soil in the field scene at the ridge by the locus N.
It is configured so that it can be cut out and bounced up toward the old ridge.

Reference numeral 10 denotes a cover member.
Consists of a side cover member 10a and a ridge side cover member 10b,
Attached to machine frame 3 above, in this case attached to machine frame 3
The rotor of the rotating rotor 5 is attached to the machine frame side cover member 10a.
The shaft 5c is installed, and the machine frame side cover member 10a is rotated.
Above the machine frame 3 side of the rotor 5 above the machine frame side and the rear surface in the traveling direction
The ridge-side cover member 10b is formed in a shape that covers half.
Has a shape that covers the upper part of the ridge side of the rotating rotor 5 and the upper part of the ridge W.
The ridge side cover member 10b is formed and the machine frame side cover portion.
Arrow as the width direction of the ridge on the material 10a by the soil volume adjustment mechanism T
It is mounted so that it can move freely in the direction of the mark, in this case
Joint mechanism T is bolt T₁, Long hole T_TwoAnd nut T_ThreeBy
On the rear side in the traveling direction of the ridge side cover member 10a.
Is formed with an embankment outlet 10c, and is located above the embankment outlet 10c.
An elastic cover 10d made of rubber or the like is
The upper surface W of the ridge is erected and is provided on the ridge side cover member 10b.
₁Side cover that can move up and down following the ridges
The member 11 is attached by the copying mechanism F.
The mechanism F includes a pair of opposed flank side surfaces of the ridge side cover member 10b.
Guide roller F₁Are arranged up and down and before and after a total of four sets.
A pair of upper and lower guide rolls F facing each other₁Guide rod F between_TwoTo
Vertically movable up and down, the front and rear guide rods F _TwoLower end
Pivotally attached to the side cover member 11 so that the side cover
The bottom surface of the member 11 is weighed by its own weight.₁Sliding on
Make up.

[0012] 12 is a Seiaze mechanism, one side W ₂ and the upper surface W ₁ capable Seiaze rotation Seiaze body 1 of ridge in this case ridges W
It comprises a 3, rotating Seiaze body 13 is forced to rotate in the arrow direction about the rotation axis P ₁ by a rotation mechanism 14.

[0013] In this case, the rotation Seiaze body 13, one side surface W ₂ of Seiaze possible conical lower rotating integer rotating roll which has an outer peripheral surface 15a around the rotation axis P ₁ of the ridge W and Azetai 15, the upper surface W ₁ of the ridge of Seiaze possible cylindrical outer peripheral surface 16
It made rotating roll-shaped upper rotating Seiaze member 16 for centering the rotation axis P ₂ have a, the lower rotary Seiaze 15
Is formed in an umbrella shape having a conical inner peripheral surface 15b, and the upper rotary ridge member 16 is formed in a cylindrical shape in which the lower rotary ridge member 15 side opens in a trumpet shape. The rotation ridge 15 and the upper rotation ridge 16 are formed so as to be superimposable with each other, and the rotation axis P ₁ of the lower rotation ridge 15 is shifted from the side of one side W ₁ of the ridge W to the ridge W side. It is arranged in the upward direction at a predetermined angle θ that is diagonally upward, and furthermore, a height adjustment mechanism 17 that can adjust the upper rotary ridge structure 15 up and down is arranged.

In this case, the edge B on the machine frame 3 side of the embankment discharge port 10c formed on the rear surface of the ridge side cover member 10b as the cover member 10 in the traveling direction is used as the rotary ridge body 13. The outermost edge C ₁ of the outer peripheral surface 15a of the lower rotary ridge body 15 capable of clamping one side of the ridge, ie, FIG.
Inside, the outer peripheral surface 15a is formed so as to conform to the uppermost point of the outer peripheral edge C of the outer peripheral edge.

In this case, a bracket 18 is protruded from a lower portion of a rear surface of the cover member 10 attached to the machine frame 3, and a bearing cylinder 19 is provided on the bracket 18 with an elongated hole 20a and a bolt 20b.
The bearing cylinder 1
9, a drive shaft 21 is rotatably supported obliquely upward at a predetermined angle θ, and the drive shaft 21 is directly connected to the rotor shaft 15c of the lower rotary ridge 15 having a truncated cone shape and an umbrella shape. A frame 22 is suspended from the rear side surface of the frame 3, a chain mechanism 23 is provided in the frame 22, the chain mechanism 23 and the main shaft 7 are conductively connected by a gear mechanism 24, and the chain mechanism 23 and the drive shaft 21 are connected. The bracket 26 is connected to the upper and lower surfaces of the cover member 10 via a telescopic universal joint 25, and a bearing tube 27 is laterally provided on the bracket 26 via a height adjustment mechanism 17. A shaft 28 is rotatably mounted horizontally, and a gear mechanism 29 which is conductively connected to the main shaft 7 is provided at a rear portion of the machine frame 3.
8 are connected by a telescopic universal joint 30, a support frame 31 is protruded from the bearing cylinder 27, a drive shaft 32 is provided horizontally below the support frame 31, and the drive shaft 32 and the intermediate shaft 28 are connected to each other. The drive shaft 32 and the rotor shaft 16c of the upper rotary ridge 16 are directly connected to each other, and the main shaft 7
Rotation lowering ridge 15 and upper rotation ridge 1 by rotation of
6 is rotated in the direction of the arrow in the figure, and one side surface W ₂ of the ridge W is tightened by the rotational contact of the lower rotary ridge member 15, and the upper surface W of the ridge W is pressed by the upper rotary ridge roll 16. It is configured so that the ridges are arranged.

In this case, as the height adjusting mechanism 17, two guide rods 17b are mounted on a base plate 17a.
A slide plate 17c is slidably mounted on the guide rod 17b, and a screw rod 17d is mounted on the base plate 17a.
Is screwed to the slide plate 17c, and the handle 1 is attached to the screw rod 17d.
7e, and a slide plate 17c is provided so as to be able to advance and retreat by a forward / reverse rotation operation of a handle 17e. Thus, the base plate 17a is fixed to the bracket 26 and the bearing cylinder 27 is attached to the slide plate 17c. The upper rotating ridge body 16 is fixed obliquely and the upper rotating ridge body 16 is brought close to the trumpet-shaped leading edge inner surface 16b of the upper rotating ridge member 16 along the outer peripheral surface 15a of the lower ridge rotating body 15 by the forward / reverse rotation operation of the handle 17e. It is configured so that it can be adjusted up and down as it is.

[0017] 35 is a loss prevention plate, the outer edge peripheral portion C of the outer peripheral surface 15a of the Shime圧possible lower rotary Seiaze member 15 one side W ₂ of the ridge W as the rotational Seiaze 13 Is protruded from the machine frame-side cover member 10a at a lower position of the vehicle, and the traveling direction is from a lower portion between the rear surface of the machine frame-side cover member 10a and the outer peripheral edge portion C of the lower rotary ridge member 15. It is designed to prevent the loss of the embankment backward.

Numeral 36 denotes a reaction force receiving mechanism. In this case, a reaction force receiving member 38 is provided on the rear surface of the machine frame side cover member 10a so as to be vertically adjustable by a vertical adjusting mechanism 37. Is a plate material and the front part in the traveling direction is an arc-shaped part 38
The lower part of the reaction force receiving body 38 is penetrated into the field M near the base of the ridge, and can receive the ridge reaction force generated by the ridge operation by the ridge mechanism 12. .

In this case, as the vertical adjustment mechanism 37, two guide rods 37b are mounted on a base plate 37a, a slide plate 37c is mounted on the guide rod 37b so as to be slidable, and a screw rod 37d is mounted on the base plate 37a. The screw 37d is screwed onto the slide plate 37c, the handle 37e is fixed to the screw 37d, and the slide plate 37c is provided to be able to move forward and backward by the forward and reverse rotation operation of the handle 37e. The plate 37a is fixed to the rear surface of the cover member 10, the reaction force receiving body 38 is fixed to the slide plate 37c, and the reaction force receiving body 38 is provided so as to be vertically adjustable by the forward / reverse rotation operation of the handle 37e. .

A stabilizing member 39 is formed in a wheel shape in this case. A supporting rod 40 is attached to the rear portion of the machine frame 3 so as to be vertically adjustable, and a sliding rod 41 is slidably movable up and down on the supporting rod 40.
, And a stabilizing member 39 is attached to the sliding rod 41, the sliding rod 32 is pressed downward by the buffer spring member 42, and is grounded on the field M to achieve stable running of the machine frame 3.

Reference numeral 49 denotes a soil removal mechanism. In this case, a holding arm 50 is pivotally mounted on the front surface of the cover member 10 in the traveling direction so as to be vertically swingable concentrically with the intermediate shaft 46.
A rotor shaft 51 is rotatably mounted on the tip of the rotor, and a shaving rotor 52 having a plurality of blade-like blades on the rotor shaft 51.
, A cover 53 covering the top of the earth shaving rotor 52 is attached to the holding arm 50, an intermediate shaft 46 is installed on the top of the cover member 10, and a chain mechanism 34 is installed between the main shaft 7 and the intermediate shaft 46. A chain mechanism 54 is erected between the intermediate shaft 46 and the earth-removing rotor 52, and the upper part of the old ridge located at the front position in the traveling direction of the rotary rotor 5 of the embankment mechanism 4 is shaved by the earth-removing rotor 52 rotated by the main shaft 7. It is configured to perform rotary earth removal with an exit locus S.

Numeral 55 denotes a soil leakage prevention plate which is provided below the cover member 10a of the cover member 10 with an adjusting mechanism 5
6, the adjusting mechanism 56 is composed of a bolt 56a and an elongated hole 56b, and is configured to adjust the relative position with the cutting trace N by adjusting the projecting position of the soil leakage prevention plate 55.

Since the first embodiment of the present invention has the above-described configuration, the traveling body 1 travels along the ridge W to rotate the power take-out shaft 6, while the rotating rotor 5 of the embankment mechanism 4 rotates the field on the ridge. The mud is continuously raised and raised on the old ridge, and the cover member 10 and the side cover member 11 prevent the mud from scattering above the rotating rotor 5 and to the side of the ridge. The levee arrangement mechanism 12 is driven, and the rotating ridge body 13 is rotated by the rotating mechanism 14. In this case, the rotating ridge body 13 adjusts one side surface W ₂ of the ridge W. becomes the ridges can lower rotary Seiaze body 15 and the upper surface W ₁ of the ridge from Seiaze possible upper rotating Seiaze member 16. consists of a lower rotary Seiaze body 15 and the upper rotary Seiaze body 16 rotates Seiaze 13
It rotated by the rotation mechanism 14, a first side surface W ₂ and the upper surface W ₁ of the ridge of the ridge W can be clamped voltage rectifier ridge, ridge by rolling contact of the rotating Seiaze body 13 it is possible to simplify the structure W one side W ₂ and can be smoothly clamped voltage rectifier ridges the upper surface W ₁ of the ridge W of this time, the rotation axis P ₁ of the lower rotary Seiaze body 15 as a rotary Seiaze body 13 of the ridge W on the other hand since the place in an upward direction of a predetermined angle θ toward the obliquely upward to the ridge W side from the side of the side surface W _1, when compared with placing the rotation axis of the rotary Seiaze body horizontally structure, rotation Seiaze Body 13, in this case, outer peripheral surface 15 on the front side in the traveling direction of lower rotating ridge body 15
it is possible to lengthen the one pressing the feed length L of the soil to the side surface W ₂ of ridge W made by the a, rotating Seiaze body 13 it is possible to assume correspondingly better the clamping pressure of the soil,
In this case, the height H in the vertical direction of the lower rotating ridge body 15 can be reduced in comparison with the structure in which the rotation axis of the rotating ridge body is arranged in the horizontal direction, and the height of the entire apparatus is accordingly reduced. In this case, the cover member 10 includes a machine frame side cover member 10a and a ridge side cover member 10b, and the ridge side cover member 10b
Is provided with a soil volume adjusting mechanism T capable of moving and adjusting the width in the width direction of the ridge. Therefore, the embankment D raised by the embankment mechanism 4 by the ridge side cover member 10b is positioned forward of the rotating ridge body 12 in the traveling direction. Can be reliably guided, and by adjusting the ridge side cover member 10b in the ridge width direction, the rotating ridge body 1
The soil volume of the embankment to the front position in the traveling direction of No. 2 can be adjusted, so that the tightening ridges can be satisfactorily adjusted by the rotary ridges 12 and a more robust ridge can be obtained.

[0024] is provided with the slidable contact side cover member 11 on the upper surface W ₁ of the ridge W in the ridge-side cover member 10b, and fill to prevent loss of embankment D that is raised by the embankment mechanism 4 can be reliably guided in the direction of travel position of the rotary Seiaze body 12, also in this case in sliding contact with the side cover member 11 on the upper surface W ₁ of the ridge W provided vertically movable by following its undulations Therefore, loss of the embankment D raised by the embankment mechanism 4 can be reliably prevented.

The rotary rotor 5 is provided with a plurality of crushing blades E radially arranged on the front side in the traveling direction and a plurality of jumping blades E radially arranged on the rear side in the traveling direction. Therefore, along with the progress, the old levee can be surely crushed by the crushing blade E first, and then the crushed soil can be flipped up by the jumping blade G, and the crushed soil can be removed accordingly. The ridge can be reliably raised on the old ridge, the binding property between the embankment and the old ridge becomes good, and the tightening ridge by the rotating ridge body is satisfactorily performed, so that a more robust ridge can be obtained.

In this case, the crushing blade E is formed in a shape in which the tip is straight or slightly twisted, and the jumping blade G is formed in a shape in which the tip is twisted. The performance and the jumping efficiency by the jump blade G can be improved.

Furthermore, in this case rotation Seiaze body 13, a first side surface W ₂ Seiaze possible upper rotating Seiaze body 16 an upper surface W ₁ of Seiaze possible lower rotary Seiaze body 15 and ridges of ridges W And the rotation axis P ₁ of the lower rotary ridge body 15 is arranged in the upward direction at a predetermined angle θ that is obliquely upward from the side of the one side surface W ₂ of the ridge W to the ridge side. it can be set Azetai 15 and the rotation of the upper rotating Seiaze body 16 at different rotational speed, respectively, can be much to one side W ₂ and satisfactorily tighten voltage rectifier ridges the upper surface W ₁ of the ridge of the ridge W.

Moreover, in this case, the old ridge surface can be previously shaved by the shaving mechanism 49, and the embankment mechanism 4 is placed on the shaved ridge surface.
Since the embankment is to be embanked, the binding property between the old embankment and the embankment can be enhanced, and a firmer embankment can be obtained.

Furthermore, one side W ₂ capable Shime圧rotation Seiaze of machine frame 3 side of the rim B of the ridge W embankment outlet 10c formed in the traveling direction rear surface of the case cover member 10 13
Because it constitutes adapt the outermost edge portion C ₁ of the outer peripheral surface 15a of the lower rotary Seiaze body 15 as, rotating rotor 5
The embankment D raised by the embankment has a wide mouth embankment exit 10
through c sent also smoothly to one side W ₂ side and its base side of the ridge, the supply of the embankment is turned into good in much to the forward position of the lower rotating Seiaze body 15 as a rotary Seiaze body 13, the old ridge The embankment can be satisfactorily pressed against one side of the ridge, and a robust ridge can be obtained.

Further, in this case, the lower rotating ridge body 1 capable of compressing one side face W ₂ of the ridge W as the rotating ridge body 13.
Since the loss prevention plate is provided at a position below the outer peripheral edge portion C of the outer peripheral surface 15a of the No. 5, it is possible to prevent the loss of the embankment rearward in the traveling direction, and accordingly, the lower rotation as the rotary ridge 13 The amount of embankment at the front position of the ridge 15 can be ensured, and the pressure of embankment on one side surface of the old ridge can be satisfactorily performed.

In this case, since the vertical adjusting mechanism 20 for vertically adjusting the lower rotating ridge 15 as the rotating ridge 13 is provided, the vertical adjusting mechanism 20 can be adjusted according to the height of the ridge. It is possible to cope with different row heights depending on the region and location.

Further, in this case, since the upper rotary ridge 15 is provided with a height adjusting mechanism 17 capable of adjusting the height, the upper rotary ridge body 15 is combined with the vertical adjusting mechanism 20 so as to be suitable for different regions and places. It is possible to cope with different heights of the ridges, and accordingly, it is possible to perform the ridge work according to the height of the ridges W.

Further, in this case, since the reaction force receiving mechanism 36 having the reaction force receiving body 38 for receiving the reaction force against the machine ridge 3 generated by the ridge arrangement mechanism 12 is provided, the tightening ridge is controlled. A plurality of reaction force receiving bodies 38 of the reaction force receiving mechanism 36 receive the accompanying ridge reaction force.
And the presence of the plurality of reaction force receiving bodies 36 can reliably receive the ridge reaction force, and the ridge ridge mechanism 12 can satisfactorily perform the tightening ridge and the ridge which is robust Can be obtained.

In this case, since the reaction force receiving member 38 is provided so as to be vertically adjustable by the vertical adjusting mechanism 37, the degree of penetration of the reaction force receiving member 38 into the field M below the reaction force receiving member 38 can be adjusted. And a good ridge development can be ensured accordingly.

The second embodiment shown in FIGS.
2 shows another example structure of the rotating ridge 13 in this case. In this case,
Rotation Seiaze body 13 is made has an outer peripheral surface 13b of the upper surface W ₁ of Seiaze possible cylindrical one side W ₂ Seiaze possible outer peripheral surface 13a and the ridge W of ridge W, and the rotation Seiaze The rotation axis P ₁ of the body 13 is disposed in the upward direction at a predetermined angle θ that is obliquely upward from the side of the one side surface W ₁ of the ridge W toward the ridge W side. P ₁ becomes attached to the rotor shaft 13c of the rotary Seiaze body 13 to the drive shaft 21 which rotates about a, and the upper rotary Seiaze body 16,
The drive transmission system, the height adjustment mechanism 17 and its accompanying parts are eliminated, and the structure of the cover member 10 is configured in the same manner as in the first embodiment. The same as the embodiment, a crushing blade E and a jumping blade G are provided, and further, an opening on the machine frame 3 side of the embankment discharge port 10c formed on the rear surface in the traveling direction of the ridge side cover member 10b as the cover member 10. the edges B, outermost edges C ₁ of the one side surface capable Shime圧outer peripheral surface 13a of the ridge of the rotary Seiaze body 13, i.e., in FIG. 9, the outer edge of the outer peripheral surface 13a It is formed so as to conform to a portion corresponding to the uppermost point of the peripheral portion C.

In the second embodiment, the same operation and effects as those of the first embodiment are obtained, and the ridge arrangement mechanism 1 is provided.
As 2, the structure is simplified because one side surface W ₂ of the ridge and the upper surface W ₁ of the ridge are constituted by the rotating ridge body 13 capable of arranging the ridge and the rotating mechanism 14 for rotating the ridge ridge 13. the rotation sliding contact of the rotary Seiaze body 13 it is possible to, one side W ₂ and the upper surface W ₁ of the ridge of the ridge W is smoothly clamped voltage rectifier ridges, the top surface W ₁ and on the other hand side W ₂ of the ridge W The ridges can be arranged well.

The present invention is not limited to the above embodiment, and the structure of the cover member 10 and the structure of the soil volume adjusting mechanism T are appropriately selected.
Can be configured to move and adjust the side cover member 11 included in the ridge in the ridge width direction, and a rotating rotor having a rotation axis in a direction intersecting with the ridge can be adopted as the embankment mechanism 4. A hydraulic motor may be used as the mechanism 14, and the structure of the elevation adjustment mechanism 17, the up-and-down adjustment mechanism 20, and the like are appropriately changed and designed.

Further, the rotary ridge 13, the lower rotary ridge 15, and the upper rotary ridge 16 in the above embodiment can be vibrated by a hydraulic or eccentric weight type vibration mechanism, or a crank type or hydraulic type can be used. An additional structure may be adopted in which a ridge hitting motion is performed by a ridge hitting mechanism of a type.

[0039]

As described above, according to the first aspect of the present invention, when the traveling body travels along the ridge, the rotating rotor as the embankment mechanism puts the mud on the ridge on the old ridge. The swelling and cover members prevent the mud from scattering, and on the other hand, the ridge arrangement mechanism is driven, and the rotating ridge body will tighten and level one side of the ridge and the upper surface of the ridge. The rotation axis of the ridge is arranged in the upward direction at a predetermined angle from the side of one side of the ridge to the ridge side diagonally upward. The length of pressing the soil against one side of the ridge made by the outer peripheral surface on the front side in the traveling direction of the ridge can be lengthened, so that the soil compaction pressure can be improved and the rotation ridge can be adjusted. Rotate the vertical height of the body Horizontally rotate the rotation axis of the ridge The height of the entire device can be reduced and the size of the device can be reduced. Consisting of a cover member,
Since the ridge side cover member is provided with a soil volume adjustment mechanism that can adjust the movement in the width direction of the ridge, the embankment raised by the embankment mechanism by the ridge side cover member is positioned at the front position in the traveling direction of the rotating ridge. It is possible to reliably guide, and it is possible to adjust the soil volume of the embankment to the front position in the traveling direction of the rotating ridge by adjusting the ridge width direction of the ridge side cover member, and the tightening pressure by the rotating ridge The ridge can be adjusted well,
A more robust ridge can be obtained.

According to the second aspect of the present invention, since the ridge side cover member is provided with a side cover member that can slide on the upper surface of the ridge, loss of the embankment raised by the embankment mechanism can be prevented. In this way, the embankment can be reliably guided to the front position in the traveling direction of the rotary ridge, and in the invention according to claim 3, the side cover member is slid on the upper surface of the ridge to undulate. In this manner, the embankment can be freely moved up and down, so that the embankment raised by the embankment mechanism can be reliably prevented from being lost.

Further, in the invention according to claim 4, the rotating ridge body comprises a lower rotating ridge member capable of arranging one side surface of the ridge and an upper rotating ridge member capable of arranging the upper surface of the ridge. The lower rotating ridge is composed of a ridge and the rotation axis of the lower rotating ridge is arranged in the upward direction at a predetermined angle from the side of one side of the ridge to the ridge side diagonally upward. And the rotation of the upper rotation ridge body can be set to different rotation speeds respectively, so that the one side surface of the ridge and the upper surface of the ridge can be satisfactorily tightened and aligned, and the invention according to claim 5 If so, the old furrow surface can be excavated in advance by the excavation mechanism, and the embankment mechanism will fill the excavated levee surface,
The bondability between the old ridge and the embankment can be improved, and a stronger ridge can be obtained accordingly.

As described above, the intended purpose can be sufficiently achieved.

[Brief description of the drawings]

FIG. 1 is an overall side view of a first embodiment of the present invention.

FIG. 2 is an overall plan sectional view of the first embodiment of the present invention.

FIG. 3 is a partial side view of the first embodiment of the present invention.

FIG. 4 is a partial side sectional view of the first embodiment of the present invention.

FIG. 5 is a rear view of the first embodiment of the present invention.

FIG. 6 is a partially enlarged rear view of the first embodiment of the present invention.

FIG. 7 is a partial rear sectional view of the first embodiment of the present invention.

FIG. 8 is a front view of the first embodiment of the present invention.

FIG. 9 is a rear view of the second embodiment of the present invention.

FIG. 10 is a plan sectional view of a second embodiment of the present invention.

FIG. 11 is a partially enlarged rear view of the second embodiment of the present invention.

[Description of Signs] W Ridge W ₁ Top surface W ₂ One side surface θ Predetermined angle P ₁ Rotation axis T Soil volume adjustment mechanism 1 Running body 2 Connecting mechanism 3 Machine frame 4 Filling mechanism 5 Rotor rotor 10 Cover member 10a Machine frame side cover member 10b ridge side cover member 11 side cover member 12 ridge arrangement mechanism 13 rotating ridge body 15 lower rotating ridge body 16 upper rotating ridge body 49 soil removal mechanism

Claims (5)

[Claims] 1. An embankment mechanism for connecting a machine frame to a traveling machine body by a connecting mechanism, and providing an embankment mechanism for raising the soil on an old ridge on the machine frame.
A cover member is provided above the embankment mechanism, and a lining mechanism capable of squeezing and embedding the embankment is provided at a position rearward in the traveling direction of the embankment mechanism. The rotation ridge is arranged in an upward direction at a predetermined angle from the side of one side of the ridge to the ridge side, and the cover member is provided with a machine frame. A levitation machine comprising a side cover member and a ridge side cover member, wherein the ridge side cover member is provided with a soil volume adjusting mechanism capable of adjusting the movement of the ridge side cover member in the width direction of the ridge. 2. The ridge-removing machine according to claim 1, wherein the ridge-side cover member is provided with a side cover member that can slide on the upper surface of the ridge. 3. The ridge-rowing machine according to claim 1, wherein the side cover member is slidably contacted with the upper surface of the ridge so as to be movable up and down in accordance with the undulation. 4. The above-mentioned rotating ridge body comprises a lower rotating ridge member capable of lining one side of the ridge and an upper rotating ridge member capable of lining the upper surface of the ridge. 2. The structure according to claim 1, wherein the rotation axis is arranged in an upward direction at a predetermined angle obliquely upward from one side of the ridge to the ridge.
4. A ridge machine according to any one of claims 3 to 3. 5. The levee-removing machine according to claim 1, further comprising a soil-removing mechanism for shaving an upper surface of an old ridge at a position forward of the embankment mechanism in the traveling direction.