JP2004278034A - Soil excavating tool - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a soil excavating tool effectively executable in a wide range of soil including soil hard to excavate by a conventional technology. <P>SOLUTION: This soil excavating tool 1 has a shaft body 4, a spiral blade 5 provided around the shaft body 4, and a plurality of soil cutting claws 9 provided at the outer peripheral part of the spiral blade 5. Excavating capacity can thereby be improved by the plurality of soil cutting claws 9 provided at the outer peripheral part of the spiral blade 5, and soil in a mud stone layer or soil mixed with cobble stones can be excavated in a short time. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a soil excavation tool for excavating soil underground.
[0002]
2. Description of the Related Art Japanese Unexamined Patent Publication (Kokai) No. H11-15083 discloses a head pipe, a shaft, and a helical blade attached around the shaft. The soil excavation tool, which is configured so that both ends are thin and the claw is provided on the upper and lower surfaces of the spiral blade, and excavates the soil while squirting compressed air from the leading conduit, to a predetermined depth After reaching the ground, the soil excavation tool is rotated in the reverse direction, the cement milk is injected from the spiral blades while stirring the soil, and the soil and cement milk are mixed. It is described that an improved construction of soft ground can be realized without generating wastewater containing milk and without causing environmental problems. A cutting tip is provided at the tip of the leading conduit of this device.
[0003] Patent Document 2 discloses a drill for a drilling machine having a sawtooth-shaped root cutting blade attached downward at a substantially drilling radius position in an outer peripheral portion near a drill tip. This drill is used in a hand-held excavator. Holes are dug while cutting a root stretched almost horizontally by a saw-shaped root cutting blade.
[0004]
[Patent Document 1] Pamphlet of International Publication No. 03/006785 [Patent Document 2] Japanese Utility Model Publication No. Sho 61-58163
According to the invention of Patent Document 1, a pile is formed in the ground by mixing with cement milk while excavating and agitating soil with spiral blades. It can be constructed without generating sludge. This technique is effective when applied to soft ground, but the problem is that drilling takes a long time in a hard soil layer with an N value of more than 30, for example, a soil layer, due to insufficient excavation power. There are points. In addition, it is difficult to perform construction in soil containing a large amount of cobblestone. Further, if an attempt is made to forcibly excavate on these soils, excessive force may be applied to the spiral blades and the equipment may be damaged.
Since the drill for a drilling machine of Patent Document 2 has a root cutting blade, it is possible to dig a hole while cutting a root stretched almost horizontally, so that the operation is more efficient than the case of using only a helical plate. Become However, this excavator drill is used by setting it in a hand-held excavator, and is used for digging a hole around a tree in an orchard and applying fertilization using this hole. Therefore, it is not applicable to large-scale construction work such as ground improvement. Therefore, the root cutting blades are only capable of cutting the roots of the tree, and are not capable of excavating soil containing a clay layer or a cobblestone.
An object of the present invention is to provide a soil excavation tool that can be effectively constructed on a wide range of soil including soil that is difficult to excavate with conventional techniques.
[0008]
In order to achieve the above object, a soil excavation tool according to the present invention comprises a shaft, a spiral blade provided around the shaft, and an outer periphery of the spiral blade. And a plurality of soil cutting claws provided in the section. The soil cutting claw is a triangular flat plate, and the lower side of the triangle may be attached such that the traveling direction side is lower. Alternatively, it is assumed that the soil cutting claw is formed of a claw body having a substantially rectangular shape and a corner on the opposite side of the traveling direction being cut off, and a cutting tip provided so as to protrude outward from the claw body. be able to. The cutting tip may be provided on a lower side of the claw body, or may be provided on a side of the claw body on the traveling direction side. The outer periphery of the spiral blade has a shape in which a diameter increases from a lower portion toward a central portion, and a diameter decreases toward an upper portion.The soil cutting claw is provided from a lower portion to a central portion of the spiral blade. It can also be. It is preferable that the soil cutting nails are provided at regular intervals on an outer peripheral portion of the spiral blade, and it is particularly preferable that an interval between the soil cutting nails is 200 mm or more and less than 400 mm.
[0009]
Embodiments of the present invention will be described below. FIG. 1 is a front view showing an example of a soil excavation tool according to the present invention. The soil excavating tool 1 according to the present invention has a leading pipe 2 at the tip, and a cutting tip 3 is provided at the tip of the leading pipe 2. While cutting the ground with the cutting tip 3, the front pipe 2 enters the ground. A shaft 4 is provided following the leading conduit 2, and a helical blade 5 is provided therearound. Although the shaft body 4 is hollow, the portion where the spiral blades 5 are provided as shown in FIG. 1 is configured such that the central portion is thick and both ends are thin along the axial direction. Here, as shown in FIG. 1, the shape is such that a cone is connected to both sides of the cylinder, and the diameter increases from both ends toward the center. Then, even in the overall shape including the spiral blades 5, the diameter increases as a whole from both ends toward the center. In the example shown in FIG. 1, the maximum diameter of the spiral blade 5 is 1000 mm. In addition, the length of the shaft body 4 is about 800 mm, and about 160 mm in the center portion has a constant thickness, and the shaft diameter changes at a constant rate from about 140 mm to about 400 mm in a range of about 320 mm above and below. And its taper angle is about 22 °. As will be described later, the taper angle of the shaft 4 has a useful function to smoothly send the earth and sand backward when the spiral blade 5 advances in the ground, but it is 22 ° in order to sufficiently exhibit such a function. It is preferable to set the degree to about. The pitch of the spiral blades 5 is such that the spiral blades 5 make a full round every 160 mm in the axial direction, and make five rounds along the length of the shaft body 4. In the range where the shaft body 4 is tapered, the outer diameter of the spiral blade 5 increases at a constant rate toward the center. On the other hand, in the range where the thickness of the shaft body 4 is constant, the outer diameter of the spiral blade 5 is also constant. In this example, the spiral blade 5 has a full circumference with the maximum outer diameter, and the outer shape forms a perfect circle when viewed from the lower side, so that the shaft may shake during digging. It goes straight straight without.
Although the shaft body 4 is hollow, an inner tube is provided therein, and the inner tube is connected to an injecting agent injection nozzle 7 (injecting agent discharge port). The injection agent injection nozzle 7 is provided outward at a position where the diameter of the shaft body 4 is largest. The gap between the shaft body 4 and the inner tube becomes a passage for compressed air, and compressed air can be ejected from an air ejection port 8 provided at the tip of the leading conduit 2.
A plurality of rectangular plate-like claws 6 are attached to the upper and lower surfaces of the spiral blade 6 respectively. The claw 6 is provided in a direction in contact with the circumference around the shaft 4, that is, such that the thickness direction of the claw 6 is in the radial direction. Mounting in this direction makes it more difficult for sludge to be generated. FIG. 2 is an enlarged perspective view of the claw 6. One corner of the rectangular shape of the nail 6 is chamfered. In this chamfering, the corner may be cut off with a straight line or may be rounded. The chamfered corner is directed according to the rotation direction of the spiral blade 5. In this example, when the digging proceeds, the helical blade 5 rotates in the forward rotation direction, but the claw 6b provided on the upper surface of the spiral blade 5 is attached with the chamfered corner facing the side facing the rotation direction. When the soil excavation tool 1 is pulled up, it rotates in the opposite direction, but the claw 6a provided on the lower surface of the spiral blade 5 is attached with the chamfered corner facing the side facing the traveling direction at this time. By directing in this manner, when digging, the nail 6a provided on the lower surface of the spiral blade 5 effectively agitates the soil while sharply penetrating the soil, while the nail 6b provided on the upper surface cuts and agitates. Smooth soil is sent backward, making it difficult to bite even if fist-sized stones are mixed. Conversely, when lifting, the claw 6b provided on the upper surface of the spiral blade 5 effectively cuts and agitates the soil, and the claw 6a provided on the lower surface smoothly sends the soil backward.
FIG. 6 shows an example of the arrangement of the claws 6 on the spiral blade 5. In this example, the maximum diameter of the spiral blade 5 is 1000 mm, and the claw 6 is 60 mm long, 50 mm high, 9 mm thick and 10 mm chamfered. The pawls are provided in a certain order according to the rotation angle about the axis as seen in FIG. A claw is attached near the outer periphery of the spiral blade 5 every one-sixth, that is, every 60 °, and one claw is attached near the shaft at the same angle. One claw is attached at one-twelfth rotation from the angle where the claw is located near the outer circumference, that is, at an angle shifted by 30 °, but the position of this claw in the radial direction is near the middle of the previous two claws. It becomes. That is, one nail and two nails are alternately arranged in a staggered manner every 30 °. In the narrow portion near the upper end and the lower end of the spiral blade 5, one claw may be continuously arranged, but even in such a case, it is preferable that the positions in the radial direction are alternately changed. The upper and lower surfaces of the spiral blade 5 have the same arrangement. Therefore, near the lower end of the spiral blade 5, a substantially conical shape is formed by the claw 6 arranged near the outer periphery and the cutting tip 3 provided on the leading conduit portion, and the soil is effectively cut like a drill. And the soil is effectively agitated by the staggered claws.
In addition to the above-mentioned claw 6, the soil excavating tool 1 has a plurality of soil cutting claws 9 on the outer periphery of the spiral blade 5. FIG. 3 shows an example of the soil cutting nail 9. A triangular flat plate is attached to the outer periphery of the spiral blade 5 by welding or the like so as to match the tangential direction of the outer periphery. During the digging, the rotation of the spiral blade 5 causes the soil cutting claw 9 to move leftward in FIG. The lower side of the triangle is mounted so that the traveling direction side is lower, that is, the sharp corner faces the opposite side in the traveling direction. The soil cutting claw 9 of this example is a simple one having no cutting tip, but has a sufficient effect on a hard soil layer having an N value of more than 30, for example, a soil layer, and reduces the time required for excavation. Can be shortened.
FIG. 4 shows an example of the soil cutting nail 9. The soil cutting nail 9 is an example of an effective one mainly for a hard soil layer having an N value exceeding 30 such as a soil layer. The soil cutting nail 9 includes a substantially rectangular nail body 10 and a cutting tip 11 provided on the nail body 10. The nail body 10 is substantially rectangular, and has a size of, for example, about 50 mm in length and 60 mm in width. As the spiral blade 5 rotates, the soil cutting claw 9 advances leftward in FIG. The opposite side of this traveling direction, that is, the lower right corner in FIG. 4 is cut off. The corner may be cut off with a straight line or may be rounded. The claw body 10 may be chamfered over the entire upper side to finish the pentagonal shape.
A cutting tip 11 is provided at the lower left portion of the claw body 10 so that the tip protrudes. In the example of FIG. 4, the cutting tip 11 is provided on the lower side of the claw body 10, and the tip of the cutting tip 11 protrudes slightly downward to the left. The cutting tip 11 is made of a special steel having a high hardness, has a sharp tip, and has a groove having a width substantially equal to the thickness of the claw body 10 so as to engage with the claw body 10. Is provided. The groove is engaged with the claw body 10, and the entire circumference is fixed by silver brazing.
FIG. 5 shows another example of the soil cutting claw 9. This is an example that is suitable mainly for soils mixed with boulders. In this example, the cutting tip 11 is provided on the side of the claw body 10 on the traveling direction side, that is, on the left side, and the tip of the cutting tip 11 projects slightly downward in the left direction. Also, the cutout of the lower right corner is larger than in the example of FIG. With this configuration, when the soil excavation tool 1 is rotated and excavated, the excavation is performed while flipping the cobblestone in the soil to the left and right of the claw body 10 with the cutting tip 11.
A plurality of soil cutting nails 9 are provided on the outer periphery of the spiral blade 5 by welding or the like, and the number thereof can be selected as appropriate according to the soil quality of the construction site. For example, by providing four soil cutting claws 9 every 90 degrees on the side close to the tip of the spiral blade, the excavating ability is considerably improved. 7 and 8 are bottom views of the spiral blade 5 as viewed from below, and show examples of the arrangement of the soil cutting claws 9. 7 and 8, the illustration of the claws 6 is omitted. FIG. 7 is an example of a spiral blade having a maximum diameter of 1500 mm, and FIG. 8 is an example of a spiral blade having a maximum diameter of 1000 mm. In both cases, the soil cutting nails 9 are arranged at intervals of 300 mm from the side close to the tip of the spiral blade 5 to a portion where the diameter of the spiral blade 5 is maximized. No soil cutting claw 9 is provided above the portion where the diameter of the spiral blade 5 is maximized. As described above, when the soil cutting claws 9 are provided in a wide range of the spiral blade 5, the interval between the soil cutting claws 9 is not an arrangement in which the angle is constant, but the distance is constant. It is preferable to arrange them. In order to obtain a sufficient excavating force, it is preferable that the interval between the soil cutting claws 9 is less than 400 mm. However, if the interval is up to about 200 mm, it is sufficient in many cases, and the interval is set to 200 mm or more. This is advantageous in terms of cost.
FIG. 9 shows an example of a construction machine using the soil excavation tool of the present invention. The work vehicle 14 has an endless track 15 and is capable of self-running, and can easily move the entire apparatus at a construction site. A leader 17 is attached to the work carriage 14 via an arm 16 that can move up and down. The reader 17 is a slide type mounting device for mounting the chuck 18 so as to be movable up and down. After moving the work cart 14 to the construction site, the angle of the arm 16 is adjusted and the leader 17 is set up vertically. The uppermost intermediate rod 13 is passed through the chuck 18, and the intermediate rod is gripped by the chuck 18. The swivel 12 is connected to the uppermost intermediate rod 13, and the soil excavation tool 1 is connected below the lowermost intermediate rod. The chuck 18 can rotate the intermediate rod 13 in both forward and reverse directions by hydraulic drive. That is, the intermediate rod 13 functions as a drive shaft for transmitting the rotation of the chuck 18 to the soil excavation tool 1 at the tip. An injection hose 19 and an air hose 20 are connected to the swivel 12, and each hose is connected to a grout pump and a compressor (not shown) of the plant. The swivel 9, the intermediate rod 13 and the soil digging tool 1 are each of a double pipe structure, but are connected so as to connect the passages of the air and the injection material.
When digging with the soil digging tool 1, air is sent by a compressor and blown out from the tip of the soil digging tool 1, and the helical blades 5 of the soil digging tool 1 are rotated so as to advance downward. After digging to some extent, add the intermediate rod 13 and dig deeper. Since the soil cutting claw 9 is provided on the outer periphery of the spiral blade 5, the soil is effectively excavated by the cutting tip 11 provided near the tip in the traveling direction. Since the claw 6a on the upper surface of the spiral blade 5 is cut off in the direction of travel, soil and sand can be smoothly sent backward even in soil where stones are mixed. Further, in order to smoothly feed the cut earth and sand backward, the outer periphery of the spiral blade 5 is shaped such that the diameter increases from the tip toward the center and decreases toward the top. In the soil excavation tool 1, the portion of the shaft body 4 to which the spiral blade 5 is attached has a thick central portion and narrow both end portions along the axial direction. Therefore, the spiral blade 5 and the shaft body 4 are strong even in the central part, and the earth and sand are smoothly sent backward while digging. Construction is possible even on hard ground or clay.
After digging to the final depth, the soil excavation tool 1 is pulled up while rotating the chuck 18 in the reverse direction and rotating the spiral blade 5 to move upward. At this time, the injection agent is introduced from the injection agent hose 19 and injected into the ground from the injection agent outlet of the soil excavation tool 1. At the time of lifting, the claw on the upper surface of the spiral blade agitates the earth and sand. The claw 6b on the lower surface of the helical blade 5 is cut off on the side of the traveling direction during the reverse rotation, so that the earth and sand can be smoothly moved backward similarly. In this construction machine, the mechanical stirring of the earth and sand and the stirring of the earth and sand by the injection of the injection agent are simultaneously performed, and the cut earth and the injection agent are efficiently mixed, and the cut earth and sand is discharged. It will not be released to the ground. When pulling up, work is performed while removing the intermediate rod in order, as opposed to digging. After raising to a predetermined height, the injection of the injection agent is stopped, and the soil excavation tool 1 is raised. When the construction of one hole is completed in this way, the work carriage 14 is moved to the next position, and the same construction is repeated.
In the construction, the intermediate rod 22 is added when digging, and the intermediate rod 22 is removed when pulling up, so that the part above the ground is kept low at all times. Since there is no need to expand the body, the construction is easy and the construction can be performed even in a narrow place or where the ground is weak.
[0022]
Embodiment 1 This is an example in which the soil excavation tool of the present invention is applied to ground improvement work on a hard soil layer having an N value of more than 30, for example, a soil layer. Therefore, as shown in FIG. 4, a soil cutting claw 9 in which the cutting tip 11 is provided on the lower side of the claw body 10 is used. In this embodiment, four soil cutting claws 9 are attached to the side close to the tip of the spiral blade every 90 degrees.
The construction machine shown in FIG. 9 is used. High-concentration cement milk is used as an injecting agent. It is preferable that the cement milk used in the present method has a higher cement ratio than in the case of the ordinary method in order to obtain sufficient strength of the improved body. Here, when the amount of cement is increased, the specific gravity of the injecting agent increases, and the suction by the pump tends to deteriorate. Therefore, it is preferable to mix a water reducing agent containing aromatic sulfone and specially modified lignin as main components. The addition of the water reducing agent makes cement milk easier to flow and makes it easier to pump, and also increases the strength of the improved body. In the construction method of this embodiment, the cut earth and sand is mixed with cement milk to form an underground pile as an improved body, and is not discharged to the ground as sludge.
Since the soil excavating tool 1 of the present invention is provided with the cutting claws 9, the conventional apparatus was able to excavate in a short time even on a hard soil layer requiring a long time for construction. For example, a conventional soil excavation tool in which a cutting claw is not provided on the outer periphery of a spiral blade can perform an excavation operation in about 5 minutes, which took 12 minutes. Thus, even if the excavation is performed at a high speed, the device is not damaged, and the soil can be sufficiently stirred.
[0025]
Embodiment 2 Next, another embodiment of the soil excavation tool of the present invention will be described. It is an example in which the soil excavation tool of the present invention is applied to soil improvement work in soil mixed with boulders. Therefore, as shown in FIG. 5, the soil cutting claw 9 in which the cutting tip 11 is provided on the side of the claw main body 10 in the traveling direction is used. In this embodiment, as shown in FIGS. 7 and 8, the soil cutting nails 9 are arranged at intervals of 300 mm from the side close to the tip of the spiral blade 5 to the portion where the diameter of the spiral blade 5 becomes maximum. Are located. No soil cutting claw 9 is provided above the portion where the diameter of the spiral blade 5 is maximized. The cutting tip 11 provided on the side of the claw body 10 on the side of the traveling direction effectively excavates the soil while repelling the cobblestone, so that the ground in the cobblestone-mixed soil, which was difficult to perform with the conventional soil excavator. The improvement work was successfully performed. Further, the spiral blade 5 was not damaged during excavation.
The embodiment of the present invention has been described above with reference to an example of application to a ground improvement work in which an underground pile is created by stirring and mixing soil with a spiral blade while injecting an injection material with a spiral blade. The application of the invention is not limited to this. The present invention can be generally applied to excavation in the ground.
[0027]
According to the soil excavator of the present invention, soil excavation work can be effectively performed even on a hard soil layer having an N value of more than 30 such as a soil layer or a cobblestone-mixed soil. In addition, the time required for excavation can be significantly reduced.
[Brief description of the drawings]
FIG. 1 is a cross section of a soil excavation tool according to the present invention.
FIG. 2 is a perspective view of a nail of a soil excavation tool.
FIG. 3 is a front view and a side view showing an example of a soil cutting nail of a soil excavating tool.
FIG. 4 is a front view and a left side view showing another example of the soil cutting nail of the soil excavation tool.
FIG. 5 is a front view showing another example of the soil cutting nail of the soil excavating tool.
FIG. 6 is a development view showing an example of arrangement of claws on a spiral blade.
FIG. 7 is a bottom view showing an example of the arrangement of soil cutting nails.
FIG. 8 is a bottom view showing another example of the arrangement of the soil cutting nails.
FIG. 9 is a front view showing the construction machine.
[Explanation of symbols]
1. Soil excavation tools2. 2. forward conduit Cutting tip4. Shaft 5. Spiral blade 6. Nails 7. Injectant outlet 8. Air outlet 9. Soil cutting nail 10. Nail body 11. Cutting tip 12. Swivel13. Intermediate rod 14. Work cart 15. Endless track Arm 17. Leader 18. Chuck 19. Injection hose 20. Air hose

Claims (8)

A soil excavation tool comprising: a shaft; a spiral blade provided around the shaft; and a plurality of soil cutting claws provided downward on an outer peripheral portion of the spiral blade. The soil excavation tool according to claim 1, wherein the soil cutting claw is a triangular flat plate, and the lower side of the triangle is attached such that the traveling direction side is lower. The nail according to claim 1, wherein the soil cutting claw is formed of a claw body having a substantially rectangular shape and a corner opposite to the traveling direction being cut off, and a cutting tip provided to protrude outward from the claw body. The described soil drilling tool. . The soil excavation tool according to claim 3, wherein the cutting tip is provided on a lower side of the claw body. The soil excavation tool according to claim 3, wherein the cutting tip is provided on a side of the claw body on the traveling direction side. The outer periphery of the spiral blade has a shape in which a diameter increases from a lower portion toward a central portion, and a diameter decreases toward an upper portion.The soil cutting claw is provided from a lower portion to a central portion of the spiral blade. The soil excavation tool according to claim 1. The soil excavation tool according to any one of claims 1 to 6, wherein the soil cutting claws are provided at regular intervals on an outer peripheral portion of the spiral blade. The soil excavation tool according to claim 7, wherein an interval between the soil cutting claws is 200 mm or more and less than 400 mm.

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