JP2021139272A - Drilling machine used in pile foundation works - Google Patents

Abstract

To provide a low noise drilling machine used in pile foundation works that after making a hole with a small diameter screw, gradually changes the same to large diameter screws and can finally complete a desired diameter pile hole.SOLUTION: A drilling machine for pile foundation works comprises a screw 5 including a first spiral piece, a second spiral piece, and a third spiral piece, and is designed for reducing a noise in drilling . The drilling machine makes a hole with the screw 5 having a small diameter first, and then makes a hole diameter larger by increasing the number of mounted spiral pieces and gradually enlarges the hole diameter, and finally finishes the drilling with the hole diameter having a desired diameter. The first spiral piece is fixed to a shaft 4, and the second spiral piece and the third spiral piece have annular spiral structures. Since their weight is lighter than that of the conventional screws 5 with the same drilling effect, a transportation cost when transporting a plurality of the screws 5 can be greatly reduced.SELECTED DRAWING: Figure 1

Description

The present invention belongs to the technical field of excavation in pile foundation work, and particularly relates to an excavation device capable of excavating with low noise.

Currently, in pile foundation work, concrete piles are an important structure that fixes the ground and buildings.
In small pile foundation work such as in urban areas, concrete piles may be constructed by excavating the ground with a screw, laying a wire cage, and injecting concrete.
When excavating this ground, loud noise may be generated, and in order to reduce this, a hole is made with a screw with a small diameter, then gradually changed to a screw with a large diameter, and finally, a screw with a desired diameter is obtained. The pile hole is being completed.
However, this method requires the preparation of screws of multiple diameters, which increases transportation costs.

For example, Pat. An underground excavation method and an apparatus provided with a switching joint means capable of shortening the time are disclosed.
According to the invention of Patent Document 1, by providing the switching joint means that can be freely switched, labor saving and rationalization of disassembly and removal of the excavation device after the completion of underground excavation can be made, and the working time can be shortened.
However, this switching joint means consists of two or more detachable auger screws having front and rear connecting parts, and when excavating from the starting pit to the reaching pit, excavation is performed by repeatedly connecting and digging the auger screws. After completion, the auger screw is separated and disassembled, and the screw is gradually changed to a screw having a larger diameter, which is a subject of the present invention, and finally, a pile hole having a desired diameter is not completed.

Japanese Patent Application Laid-Open No. 2007-197996

Therefore, in order to solve the problem of reducing noise during excavation of the ground, the present invention makes a hole with a screw having a small diameter and then gradually changes to a screw having a large diameter, and finally, a desired screw is used. Provided is a low noise excavator used for pile foundation work capable of completing a pile hole having a diameter.

In order to solve the problems in the prior art, the present invention takes the following technical solutions.
In the description of the present invention, terms such as "inside", "down", and "up" that indicate the orientation and the positional relationship are based on the orientation shown in the drawing, the orientation often placed during work, and the positional relationship. ..
In addition, the direction or positional relationship is for explaining the present invention and simplifying the description, and the referenced device or element has a specific direction and is constructed or operated in a specific direction. It does not indicate or suggest that it must be done.
Furthermore, terms such as "first" and "second" are used only to distinguish the explanations and do not mean to indicate or imply relative importance.

The excavator for pile foundation work according to the present invention is
An excavator for pile foundation work consisting of a shaft and a screw.
The screw consists of a first spiral piece, a second spiral piece, and a third spiral piece that form one normal spiral surface, which is a spiral drilling blade.
The shaft consists of a rod-shaped body in which the first spiral piece is integrally formed.
The second spiral piece is detachably attached to the outer peripheral side of the first spiral piece.
The third spiral piece is detachably attached to the outer peripheral side of the second spiral piece.
In a configuration in which a blade mechanism is fixed to the lower end of each spiral piece,
It is characterized in that noise during excavation can be reduced by sequentially attaching the first spiral piece to the third spiral piece and excavating while increasing the diameter of the hole to be excavated.

The excavator for pile foundation work according to the present invention is
An excavator for pile foundation work consisting of a shaft and a screw.
The screw consists of a first spiral piece, a second spiral piece, and a third spiral piece that form one normal spiral surface, which is a spiral drilling blade.
The shaft consists of a rod-shaped body in which the first spiral piece is integrally formed.
The second spiral piece is detachably attached to the outer peripheral side of the first spiral piece.
The third spiral piece is detachably attached to the outer peripheral side of the second spiral piece.
A blade mechanism is fixed to the lower end of each spiral piece,
An outer cylinder having a spiral notch formed like a spiral tube avoiding the first spiral piece is detachably attached to the shaft so as to cover the outer circumference in a spiral shape.
One or more positioning holes are formed in each of the shaft and the outer cylinder.
The outer cylinder is fixed to the shaft by inserting the positioning screw into the positioning hole.
On the outer peripheral surface of the outer cylinder, a plurality of drive rods with a plate piece attached to the tip are provided at equal intervals.
Due to the configuration in which the outer cylinder is fixed to the first spiral piece by the plate piece of the drive rod,
It is characterized in that noise during excavation can be reduced by sequentially attaching the first spiral piece to the third spiral piece and excavating while increasing the diameter of the hole to be excavated.

The excavator for pile foundation work according to the present invention is
An excavator for pile foundation work consisting of a shaft and a screw.
The screw consists of a first spiral piece, a second spiral piece, and a third spiral piece that form one normal spiral surface, which is a spiral drilling blade.
The shaft consists of a rod-shaped body in which the first spiral piece is integrally formed.
The second spiral piece is detachably attached to the outer peripheral side of the first spiral piece.
The third spiral piece is detachably attached to the outer peripheral side of the second spiral piece.
A blade mechanism is fixed to the lower end of each spiral piece,
An outer cylinder having a spiral notch formed like a spiral tube avoiding the first spiral piece is detachably attached to the shaft so as to cover the outer circumference in a spiral shape.
One or more positioning holes are formed in each of the shaft and the outer cylinder.
The outer cylinder is fixed to the shaft by inserting the positioning screw into the positioning hole.
On the outer peripheral surface of the outer cylinder, a plurality of drive rods with a plate piece attached to the tip are provided at equal intervals.
The outer cylinder is fixed to the first spiral piece by the plate piece of the drive rod,
A plurality of insertion grooves are formed at equal intervals along the outer peripheral edge of the first spiral piece.
A plurality of insertion plates are formed at equal intervals along the inner peripheral edge of the second spiral piece.
The second spiral piece is attached to the first spiral piece by fitting the insertion plate into the insertion groove.
A second spiral groove is formed in the second spiral piece along the outer peripheral edge.
The second spiral groove is provided with a plurality of second spiral screw holes at equal intervals along the spiral direction of the second spiral piece, and the third spiral piece has a third spiral along the inner peripheral edge. A groove is formed,
The third spiral groove is provided with a plurality of third spiral screw holes at equal intervals along the spiral direction of the third spiral piece.
After the third spiral groove was superposed on the second spiral groove and attached, the second spiral screw hole and the third spiral screw hole were fastened with a countersunk screw, and the third spiral piece was fixed to the second spiral piece. Depending on the configuration
It is characterized in that noise during excavation can be reduced by sequentially attaching the first spiral piece to the third spiral piece and excavating while increasing the diameter of the hole to be excavated.

The excavator for pile foundation work according to the present invention is
An excavator for pile foundation work consisting of a shaft and a screw.
The screw consists of a first spiral piece, a second spiral piece, and a third spiral piece that form one normal spiral surface, which is a spiral drilling blade.
The shaft consists of a rod-shaped body in which the first spiral piece is integrally formed.
The second spiral piece is detachably attached to the outer peripheral side of the first spiral piece.
The third spiral piece is detachably attached to the outer peripheral side of the second spiral piece.
At the lower ends of each of the first spiral piece, the second spiral piece, and the third spiral piece, a blade mechanism consisting of a connecting plate and a triangular blade is provided.
With a connecting plate that connects the first spiral piece and the second spiral piece, and the second spiral piece and the third spiral piece, respectively.
It is fixed by the fixing screw while being sandwiched by the U-shaped plate.
An outer cylinder having a spiral notch formed like a spiral tube avoiding the first spiral piece is detachably attached to the shaft so as to cover the outer circumference in a spiral shape.
One or more positioning holes are formed in each of the shaft and the outer cylinder.
The outer cylinder is fixed to the shaft by inserting the positioning screw into the positioning hole.
On the outer peripheral surface of the outer cylinder, a plurality of drive rods with a plate piece attached to the tip are provided at equal intervals.
The outer cylinder is fixed to the first spiral piece by the plate piece of the drive rod,
A plurality of insertion grooves are formed at equal intervals along the outer peripheral edge of the first spiral piece.
A plurality of insertion plates are formed at equal intervals along the inner peripheral edge of the second spiral piece.
The second spiral piece is attached to the first spiral piece by fitting the insertion plate into the insertion groove.
A second spiral groove is formed in the second spiral piece along the outer peripheral edge.
The second spiral groove is provided with a plurality of second spiral screw holes at equal intervals along the spiral direction of the second spiral piece, and the third spiral piece has a third spiral along the inner peripheral edge. A groove is formed,
The third spiral groove is provided with a plurality of third spiral screw holes at equal intervals along the spiral direction of the third spiral piece.
After the third spiral groove was superposed on the second spiral groove and attached, the second spiral screw hole and the third spiral screw hole were fastened with a countersunk screw, and the third spiral piece was fixed to the second spiral piece. Depending on the configuration
It is characterized in that noise during excavation can be reduced by sequentially attaching the first spiral piece to the third spiral piece and excavating while increasing the diameter of the hole to be excavated.

The beneficial effects of the present invention as compared with conventional excavation techniques are as follows.
1) The screw of the excavator of the present invention is composed of a first spiral piece, a second spiral piece, and a third spiral piece, all of which are removable. This is a configuration adopted to reduce noise during excavation. First, excavate with a screw (first spiral piece) with a small diameter, then the second spiral piece is attached to the first spiral piece, and the second spiral piece is attached to the second spiral piece. By attaching the 3rd spiral piece to, the diameter of the screw (the diameter of the hole to be drilled) can be increased, and finally, the hole with the diameter of the screw with the 3rd spiral piece attached can be drilled, which is gradually increased. By excavating so that it becomes a hole, noise during excavation can be minimized.
2) The first spiral piece, which is the screw of the excavator of the present invention, is fixed to the outer cylinder attached to the shaft, while the second spiral piece and the third spiral piece are fixed to the shaft and the outer cylinder. It is just a screw with a spiral structure. Therefore, conventionally, for example, at a site where an excavator having a diameter of only the first spiral piece, a second spiral piece, or a third spiral piece is required, a shaft having a screw of each diameter is required. Three integrated excavators must be carried, but the present invention presents the second spiral piece, two shafts attached to the third spiral piece, and the first spiral piece, the first and second spirals. As a result of reducing the weight of the three screws on one side, the transportation cost can be reduced.
3) In the excavator of the present invention, the second spiral piece has a small spiral diameter and a large rigidity, but the third spiral piece has a large spiral diameter and a relatively small rigidity. Therefore, each mounting method is changed according to this situation, but this can improve the mounting efficiency and ensure the reliability of the excavation work.

A side view showing the configuration of an embodiment of an excavator according to the present invention. Cross-sectional view of the state where the outer cylinder is attached to the shaft on which the first spiral piece is integrally formed. Perspective view showing the structure of the outer cylinder Perspective view showing the structure of the first spiral piece integrally molded with the shaft. Perspective view showing the structure of the first spiral piece with the outer cylinder attached to the shaft. Perspective view showing the structure of the second spiral piece Perspective view showing the structure of the third spiral piece Perspective view showing the mounting state of the first blade mechanism, the second blade mechanism, and the third blade mechanism. Perspective view showing the connected state of the 1st blade mechanism, the 2nd blade mechanism and the 3rd blade mechanism. Cross-sectional view showing the positional relationship of the plate pieces that fit in the groove

Examples of the present invention will be described with reference to the drawings.

As shown in FIG. 1, the drilling apparatus according to the present invention includes a shaft 4 and a screw 5.
The screw 5 is composed of a first spiral piece 8, a second spiral piece 10, and a third spiral piece 9 that form one normal spiral surface.
The shaft 4 is formed of a rod-shaped body in which a first spiral piece 8 which is a spiral excavation blade is integrally formed on an outer peripheral surface.
The second spiral piece 10 is a spiral excavation blade that is detachably attached to the outer peripheral side of the first spiral piece 8 which is a spiral excavation blade.
The third spiral piece 9 is a spiral excavation blade that is detachably attached to the outer peripheral side of the second spiral piece 10.

The shaft 4 is connected to the connecting device 1, the hydraulic motor 2, and the connecting component 3, and is attached to the output terminal of the hydraulic motor 2 via the connecting component 3.
The hydraulic motor 2 is connected to a drive component via a connecting device 1 and controls the swing and rotation of the shaft 4 via the connecting component 3.

The screw 5 is composed of the first spiral piece 8, the second spiral piece 10, and the third spiral piece 9 in order to reduce noise during excavation. First, the screw 5 has a small spiral diameter. Excavation is performed by the spiral piece 8, and then, in order to gradually increase the diameter of the hole to be excavated, the second spiral piece 10 is attached to the first spiral piece 8 and excavated, and further, the third spiral piece 9 is attached to the second spiral piece 10. Install and excavate.
As a result, the diameter of the hole to be excavated can be gradually increased.
Further, it is not always necessary to attach all the first to third spiral pieces, and any spiral piece necessary for excavating a hole having a desired diameter can be selected.

The first spiral piece 8, the second spiral piece 10, and the third spiral piece 9 are formed so as to be a spiral screw constituting one normal spiral surface. Conventionally, for example, the first spiral For sites that require excavators of each diameter up to one piece, up to the second spiral piece, and up to the third spiral piece, three shaft-integrated excavators with screws of each diameter must be carried. However, according to this embodiment, the weights of the two shafts attached to the second spiral piece and the third spiral piece, and the weights of the three screws of the first spiral piece and the first and second spiral pieces are added. As a result of the reduction, the transportation cost can be reduced.

As shown in FIG. 3, an outer cylinder 7 is detachably wound around the outer peripheral surface of the shaft 4 so as to cover the rod-shaped portion of the shaft 4.
A first spiral piece 8 which is a spiral excavating blade is integrally formed on the shaft 4.
Therefore, the outer cylinder 7 is formed with a spiral notch so as to avoid the first spiral piece 8 like a spiral pipe, and is attached so as to cover only the rod-shaped body portion of the shaft 4.
Therefore, when the outer cylinder 7 is attached to the shaft 4, the first spiral piece 8 extends from this notch.
The outer cylinder 7 protects the shaft 4 from damage due to friction with the excavated earth and sand.

A plurality of drive rods 12 are attached to the outer cylinder 7 at equal intervals so as to project from the outer cylinder 7.
As shown in FIG. 10, a plate piece 13 is attached to the tip of the drive rod 12.
A plate piece notch groove 14 is formed in the plate piece 13.
The plate piece notch groove 14 is useful for discharging the excavated earth and sand to the outer peripheral side by turning the first spiral piece 8 during excavation.

As shown in FIG. 5, the outer cylinder 7 fits into the first spiral piece 8 in a state where the plate piece 13 is placed in the recessed portion of the concave groove 19 formed in the first spiral piece 8. ..
In this way, the outer cylinder 7 is integrally attached to the shaft 4 with the plate piece 13 fitted to the first spiral piece 8.

As shown in FIG. 3, a first positioning hole 11 penetrating the shaft 4 is formed at the upper end of the outer cylinder 7.
Only one first positioning hole 11 may be formed, or two may be formed so that the axes of the through holes do not interfere with each other as shown in FIG.
As shown in FIG. 4, a second positioning hole 16 is formed in the shaft 4.
Although not shown in FIG. 4, two sets of second positioning holes 16 may be formed on the shaft 4.
By aligning the positions of the first positioning hole 11 formed in the outer cylinder 7 and the second positioning hole 16 formed in the screw 4 and inserting the positioning screw 6 there, the outer cylinder 7 is screwed 4 To be fixed to.
When two sets of the first positioning hole 11 and the second positioning hole 16 are formed, two positioning screws 6 can be inserted through the outer cylinder 7, whereby the outer cylinder 7 can be more firmly fixed to the screw 4. ..

As shown in FIGS. 4 and 10, a plurality of concave grooves 19 having a concave shape at the upper side are formed in the first spiral piece 8 at equal intervals along the outer peripheral edge of the first spiral piece 8. , Each concave groove 19 is formed with a spiral piece notch groove 18 and an insertion groove 17.
The spiral piece notch groove 18 is useful for discharging the excavated earth and sand to the outer peripheral side by turning the first spiral piece 8 during excavation.

Further, as shown in FIG. 5, a plurality of insertion plates 25 are formed at equal intervals along the inner peripheral edge of the second spiral piece 10.
The insertion plate 25 of the second spiral piece 10 fits into the insertion groove 17 formed in the concave groove 19 of the first spiral piece 8 when the second spiral piece 10 is attached to the first spiral piece 8. do.
As a result, the second spiral piece 10 is attached to the outer peripheral side of the first spiral piece 8.

As shown in FIG. 6, the second spiral piece 10 has a second spiral groove 26 formed so that the upper surface side is notched along the outer peripheral edge, and the second spiral groove 26 has a second spiral groove 26. A plurality of second spiral screw holes 27 are provided at equal intervals along the spiral direction of the two spiral pieces 10.

As shown in FIG. 7, the third spiral piece 9 has a third spiral groove 30 formed so that the lower surface side is cut out along the inner peripheral edge, and the third spiral groove 30 has a third spiral groove 30. A plurality of third spiral screw holes 29 are provided at equal intervals along the spiral direction of the third spiral piece 9.

The third spiral piece 9 is attached to the outside of the second spiral piece 10 so as to overlap the third spiral groove 30 and the second spiral groove 26, and is equidistantly spaced along the spiral direction of the second spiral piece 10. Since the plurality of second spiral screw holes 27 provided are formed so as to coincide with the plurality of third spiral screw holes 29 provided at equal intervals along the spiral direction of the third spiral piece 9. By fastening the screw holes with the countersunk screws 36, the third spiral piece 9 can be fixed to the second spiral piece 10.

When the outer cylinder 7 is attached to the shaft 4, the position of the plate piece 13 attached to the tip of the drive rod of the outer cylinder 7 in the concave groove 19 of the first spiral piece 8 is concave as shown in FIG. It is on the left side in the groove 19, and there is a gap between the first inclined surface 15 and the second inclined surface 20.
Further, even when the second spiral piece 10 is attached to the outside of the first spiral piece 8, the position of the plate piece 13 is on the left side in the concave groove 19 as shown in FIG.

This is a plate piece from above the insertion plate 25 so that the insertion plate 25 of the second spiral piece 10 does not come off from the state of being fitted in the insertion groove 17 formed in the first spiral piece 8. This is because it is suppressed by 13.
Therefore, when removing the second spiral piece 10, the outer cylinder 7 is rotated in the spiral direction, and the plate piece 13 attached to the tip of the drive rod 12 is slid to the right side in the concave groove 19.

As a result, the plate piece 13 holding the insertion plate 25 of the second spiral piece 10 disappears above the insertion groove 17 formed in the first spiral piece 8, and the insertion groove 17 is released. By removing the insertion plate 25 from the insertion groove 17, the second spiral piece 10 can be removed from the first spiral piece 8.
Further, as the plate piece 13 slides to the right side in the concave groove 19, the positions of the plate piece notch groove 14 of the plate piece 13 and the spiral piece notch groove 18 formed in the first spiral piece 8 overlap, and the top and bottom There is a space that penetrates in the direction.
Therefore, the insertion plate 25 of the second spiral piece 10 is lifted upward in the insertion groove 17, passes over the plate piece 13, and passes through the gap formed by the overlap of the plate piece notch groove 14 and the spiral piece notch groove 18. The second spiral piece 10 can be removed from the first spiral piece 8 by moving the first spiral piece 8 downward.

Further, as shown in FIG. 10, a second inclined surface 20 is formed at a corner of the concave groove 19 formed in the first spiral piece 8 opposite to the insertion groove 17, and the drive rod 12 has a second inclined surface 20 formed therein. A first inclined surface 15 is formed at the corner of the plate piece 13 attached to the tip.
Since the second inclined surface 20 and the first inclined surface 15 are formed in the concave groove 19 and the plate piece 13, the plate piece 13 is slid to the right side in the concave groove 19 and the first inclined surface 15 is formed. When is close to the second inclined surface 20 of the concave groove 19, it is possible to prevent earth and sand from being caught between the concave groove 19 and the plate piece 13, and the slide of the plate piece 13 is not hindered.

The role of the third inclined surface 37 is to prevent the excavated earth and sand from staying on the first spiral piece 8, and the top surface of the plate piece 13 protrudes from the top surface of the first spiral piece 8. Therefore, it is for reducing the resistance of earth and sand during excavation.

As shown in FIG. 4, a first blade mechanism 21 is attached to the lower end of the first spiral piece 8.
Further, as shown in FIG. 6, a second blade mechanism 28 is attached to the lower end of the second spiral piece 10.
Further, as shown in FIG. 7, a third blade mechanism 31 is attached to the lower end of the third spiral piece 9.
Therefore, when the first spiral piece 8, the second spiral piece 10, and the third spiral piece 9 are all attached, the first to third blade mechanisms 21 are attached to the lower ends of all the spiral pieces as shown in FIG. , 28, 31 are attached.

The first blade mechanism 21, the second blade mechanism 28, and the third blade mechanism 31 have exactly the same structure.
That is, the first to third blade mechanisms 21, 28, and 31 each include a connecting plate 23 and two triangular blades 24.
The connecting plate 23 is attached to the lower surface side of each lower end of the first spiral piece 8, the second spiral piece 10, and the third spiral piece 9, and the two triangular blades 24 are attached to the lower surface side of the connecting plate 23.
The triangular blade 24 can improve the excavation efficiency.

The first connecting plate 32 is placed on the top surface of each connecting plate 23 of the first blade mechanism 21 and the second blade mechanism 28, and each connecting plate 23 of the second blade mechanism 28 and the third blade mechanism 31 is placed. A second connecting plate 35 is placed on the top surface of the second blade mechanism 28 (a state in which the second connecting plate 35 is placed on the first connecting plate 32 on the top surface of the second blade mechanism 28). The first blade mechanism 21 and the first connecting plate 32, the second blade mechanism 28 and the first connecting plate 32 and the second connecting plate 35, and the third blade mechanism 31 and the second connecting plate 35 are U, respectively. It is sandwiched by the mold plate 33 and fixed by the fixing screw 34 from above the U-shaped plate 33.
As a result, the blade mechanisms 21, 28, and 31 attached to the first spiral piece 8, the second spiral piece 10, and the third spiral piece 9 are fixed, and the blade mechanisms 21, 28, and 31 and the spiral pieces 8 are fixed. The stability of 10 and 9 can be improved.

The excavator according to the present invention having the above configuration first excavates with a first spiral piece 8 having a small diameter, then attaches a second spiral piece 10 to the first spiral piece 8 and excavates, and then excavates. The third spiral piece 9 is attached to the second spiral piece 10 and excavated.
In this way, the diameter of the hole to be drilled is gradually increased to finally complete any drilled hole.
Therefore, it is not always necessary to attach all the first to third spiral pieces, and any spiral piece necessary for excavating a hole having a desired diameter can be selected.

The method of attaching each spiral piece of the excavator according to the present invention is as follows.

First, the outer cylinder 7 is attached to the shaft 4.
The outer cylinder 7 is attached to the shaft 4 while rotating around the shaft 4 in the spiral direction so that the first spiral piece 8 passes through the spiral notch.
When the outer cylinder 7 is attached to the shaft 4, the first spiral piece 8 extends from the spiral notch.
The first positioning hole 11 formed in the outer cylinder 7 and the second positioning hole 16 formed in the screw 4 are aligned with each other, and the positioning screw 6 is inserted to fix the outer cylinder 7 to the screw 4. ..
The plate piece 13 attached to the tip of the drive rod 12 is fitted into the concave groove 19 formed in the first spiral piece 8.

Next, the second spiral piece 10 is attached to the first spiral piece 8.
The insertion plate 25 of the second spiral piece 10 is aligned so as to be inserted into the insertion groove 17 formed in the first spiral piece 8, and the second spiral piece 10 is attached to the outer periphery of the first spiral piece 8.
The plate piece 13 attached to the tip of the drive rod 12 of the outer cylinder 7 is fitted in the concave groove 19 formed in the first spiral piece 8, and the plate piece 13 is above the insertion groove 17. The outer cylinder 7 is rotated in the spiral direction so as to close the position.

Then, the first connecting plate 32 is placed on the top surface of each connecting plate 23 of the first blade mechanism 21 and the second blade mechanism 28.
Each of the overlapped connecting plates 23 and the first connecting plate 32 is sandwiched by the U-shaped plate 33, and fixed from above the U-shaped plate 33 by the fixing screw 34.

Finally, the third spiral piece 9 is attached to the second spiral piece 10.
The third spiral piece 9 is spirally directed so that the lower surface side of the third spiral groove 30 formed in the third spiral piece 9 and the upper surface side of the second spiral groove 26 formed in the second spiral piece 10 overlap. Gradually slide along the outer circumference of the second spiral piece 10 while rotating to.
When the third spiral piece 9 completely overlaps the entire second spiral piece 10, the second spiral screw hole 27 on the second spiral groove 26 formed in the second spiral piece 10 and the third spiral piece 9 are formed. After confirming that the screw holes of the third spiral screw hole 29 on the formed third spiral groove 30 are overlapped with each other, the third spiral groove 30 is fixed by the countersunk screw 36.

Then, the second connecting plate 35 is placed on the top surface of each connecting plate 23 of the second blade mechanism 28 and the third blade mechanism 31.
Each of the overlapping connecting plates 23 and the second connecting plate 35 (with the second connecting plate 35 mounted on the first connecting plate 32 on the top surface of the second blade mechanism 28), respectively. It is sandwiched by the U-shaped plate 33 and fixed by the fixing screw 34 from above the U-shaped plate 33.

The method of removing each spiral piece of the excavator according to the present invention is as follows.

First, the third spiral piece 9 is removed from the second spiral piece 10.
The second connecting plate 35 for fixing the second blade mechanism 28 and the third blade mechanism 31, the U-shaped plate piece 33, and the fixing screw 34 are removed, and the third blade mechanism 31 is removed from the third spiral piece 9.
Remove the countersunk screw 36 that secures the second spiral piece 10 and the third spiral piece 9.
The third spiral piece 9 is removed from the second spiral piece 10 while being rotated in the spiral direction so as to move downward.
After removing the third spiral piece 9, the connecting plate 23 on the top surface of the second blade mechanism 28 and the first connecting plate 32 placed on the connecting plate 23 are sandwiched by the U-shaped plate piece 33, and the U-shaped plate 33 is sandwiched. By fixing with the fixing screw 34 from above, the excavator can be used with the second spiral piece 10 attached to the first spiral piece 8.

Next, the second spiral piece 10 is removed from the first spiral piece 8.
The first connecting plate 32 for fixing the first blade mechanism 21 and the second blade mechanism 28, the U-shaped plate piece 33, and the fixing screw 34 are removed, and the second blade mechanism 28 is removed from the second spiral piece 10.
The outer cylinder 7 is slightly rotated in the spiral direction, and the plate piece 13 attached to the tip of the drive rod 12 is slid to the right side in the concave groove 19.
Then, the insertion plate 25 of the second spiral piece 10 is once lifted upward from the insertion groove 17, and the gap formed by overlapping the plate piece notch groove 14 and the spiral piece notch groove 18 beyond the plate piece 13. The second spiral piece 10 is removed from the first spiral piece 8 so as to pass through.
After removing the second spiral piece 10, the connecting plate 23 on the top surface of the first blade mechanism 21 is sandwiched by the U-shaped plate piece 33, and fixed from above the U-shaped plate 33 by the fixing screw 34, the first spiral piece The excavator can be used in the state of only 8.

Finally, the outer cylinder is removed from the first spiral piece 8 (shaft 4).
The positioning screw 6 is removed from the second positioning hole 16 and the first positioning hole 11.
The plate piece 13 attached to the tip of the drive rod 12 of the outer cylinder 7 is removed from the recessed groove 19 formed in the first spiral piece 8.
The outer cylinder 7 is removed from the shaft 4 while rotating around the shaft 4 in a spiral direction.
It can also be used in the state of only the first spiral piece 8.
Finally, the shaft 4 and the first spiral piece 8 are removed from the hydraulic motor 2.

1 Connecting device 2 Hydraulic motor 3 Connecting parts 4 Shaft 5 Screw 6 Positioning screw 7 Outer cylinder 8 1st spiral piece 9 3rd spiral piece 10 2nd spiral piece 11 1st positioning hole 12 Drive rod 13 Plate piece 14 Plate piece Notch groove 15 1st slope 16 2nd positioning hole 17 Insertion groove 18 Spiral piece notch groove 19 Concave groove 20 2nd inclined surface 21 1st blade mechanism 23 Connection plate 24 Triangular blade 25 Insertion plate 26 2nd spiral groove 27 2nd spiral Screw hole 28 2nd blade mechanism 29 3rd spiral screw hole 30 3rd spiral groove 31 3rd blade mechanism 32 1st connecting plate 33 U-shaped plate piece 34 Fixing screw 35 2nd connecting plate 36 Countersunk screw 37 3rd slope

Claims (4)

An excavator for pile foundation work consisting of a shaft and a screw.
The screw consists of a first spiral piece, a second spiral piece, and a third spiral piece that form one normal spiral surface, which is a spiral drilling blade.
The shaft consists of a rod-shaped body in which the first spiral piece is integrally formed.
The second spiral piece is detachably attached to the outer peripheral side of the first spiral piece.
The third spiral piece is detachably attached to the outer peripheral side of the second spiral piece.
In a configuration in which a blade mechanism is fixed to the lower end of each spiral piece,
An excavation device for pile foundation work, which is characterized in that noise during excavation can be reduced by sequentially attaching the first spiral piece to the third spiral piece and excavating while increasing the diameter of the hole to be excavated.
An excavator for pile foundation work consisting of a shaft and a screw.
The screw consists of a first spiral piece, a second spiral piece, and a third spiral piece that form one normal spiral surface, which is a spiral drilling blade.
The shaft consists of a rod-shaped body in which the first spiral piece is integrally formed.
The second spiral piece is detachably attached to the outer peripheral side of the first spiral piece.
The third spiral piece is detachably attached to the outer peripheral side of the second spiral piece.
A blade mechanism is fixed to the lower end of each spiral piece,
An outer cylinder having a spiral notch formed like a spiral tube avoiding the first spiral piece is detachably attached to the shaft so as to cover the outer circumference in a spiral shape.
One or more positioning holes are formed in each of the shaft and the outer cylinder.
The outer cylinder is fixed to the shaft by inserting the positioning screw into the positioning hole.
On the outer peripheral surface of the outer cylinder, a plurality of drive rods with a plate piece attached to the tip are provided at equal intervals.
Due to the configuration in which the outer cylinder is fixed to the first spiral piece by the plate piece of the drive rod,
An excavation device for pile foundation work, which is characterized in that noise during excavation can be reduced by sequentially attaching the first spiral piece to the third spiral piece and excavating while increasing the diameter of the hole to be excavated.
An excavator for pile foundation work consisting of a shaft and a screw.
The screw consists of a first spiral piece, a second spiral piece, and a third spiral piece that form one normal spiral surface, which is a spiral drilling blade.
The shaft consists of a rod-shaped body in which the first spiral piece is integrally formed.
The second spiral piece is detachably attached to the outer peripheral side of the first spiral piece.
The third spiral piece is detachably attached to the outer peripheral side of the second spiral piece.
A blade mechanism is fixed to the lower end of each spiral piece,
An outer cylinder having a spiral notch formed like a spiral tube avoiding the first spiral piece is detachably attached to the shaft so as to cover the outer circumference in a spiral shape.
One or more positioning holes are formed in each of the shaft and the outer cylinder.
The outer cylinder is fixed to the shaft by inserting the positioning screw into the positioning hole.
On the outer peripheral surface of the outer cylinder, a plurality of drive rods with a plate piece attached to the tip are provided at equal intervals.
The outer cylinder is fixed to the first spiral piece by the plate piece of the drive rod,
A plurality of insertion grooves are formed at equal intervals along the outer peripheral edge of the first spiral piece.
A plurality of insertion plates are formed at equal intervals along the inner peripheral edge of the second spiral piece.
The second spiral piece is attached to the first spiral piece by fitting the insertion plate into the insertion groove.
A second spiral groove is formed in the second spiral piece along the outer peripheral edge.
The second spiral groove is provided with a plurality of second spiral screw holes at equal intervals along the spiral direction of the second spiral piece, and the third spiral piece has a third spiral along the inner peripheral edge. A groove is formed,
The third spiral groove is provided with a plurality of third spiral screw holes at equal intervals along the spiral direction of the third spiral piece.
After the third spiral groove was superposed on the second spiral groove and attached, the second spiral screw hole and the third spiral screw hole were fastened with a countersunk screw, and the third spiral piece was fixed to the second spiral piece. Depending on the configuration
An excavation device for pile foundation work, which is characterized in that noise during excavation can be reduced by sequentially attaching the first spiral piece to the third spiral piece and excavating while increasing the diameter of the hole to be excavated.
An excavator for pile foundation work consisting of a shaft and a screw.
The screw consists of a first spiral piece, a second spiral piece, and a third spiral piece that form one normal spiral surface, which is a spiral drilling blade.
The shaft consists of a rod-shaped body in which the first spiral piece is integrally formed.
The second spiral piece is detachably attached to the outer peripheral side of the first spiral piece.
The third spiral piece is detachably attached to the outer peripheral side of the second spiral piece.
At the lower ends of each of the first spiral piece, the second spiral piece, and the third spiral piece, a blade mechanism consisting of a connecting plate and a triangular blade is provided.
With a connecting plate that connects the first spiral piece and the second spiral piece, and the second spiral piece and the third spiral piece, respectively.
It is fixed by the fixing screw while being sandwiched by the U-shaped plate.
An outer cylinder having a spiral notch formed like a spiral tube avoiding the first spiral piece is detachably attached to the shaft so as to cover the outer circumference in a spiral shape.
One or more positioning holes are formed in each of the shaft and the outer cylinder.
The outer cylinder is fixed to the shaft by inserting the positioning screw into the positioning hole.
On the outer peripheral surface of the outer cylinder, a plurality of drive rods with a plate piece attached to the tip are provided at equal intervals.
The outer cylinder is fixed to the first spiral piece by the plate piece of the drive rod,
A plurality of insertion grooves are formed at equal intervals along the outer peripheral edge of the first spiral piece.
A plurality of insertion plates are formed at equal intervals along the inner peripheral edge of the second spiral piece.
The second spiral piece is attached to the first spiral piece by fitting the insertion plate into the insertion groove.
A second spiral groove is formed in the second spiral piece along the outer peripheral edge.
The second spiral groove is provided with a plurality of second spiral screw holes at equal intervals along the spiral direction of the second spiral piece, and the third spiral piece has a third spiral along the inner peripheral edge. A groove is formed,
The third spiral groove is provided with a plurality of third spiral screw holes at equal intervals along the spiral direction of the third spiral piece.
After the third spiral groove was superposed on the second spiral groove and attached, the second spiral screw hole and the third spiral screw hole were fastened with a countersunk screw, and the third spiral piece was fixed to the second spiral piece. Depending on the configuration
An excavation device for pile foundation work, which is characterized in that noise during excavation can be reduced by sequentially attaching the first spiral piece to the third spiral piece and excavating while increasing the diameter of the hole to be excavated.

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