JP6354277B2 - Ground improvement column - Google Patents

Description

  The present invention relates to a ground improvement column.

As a ground improvement technique, a soil cement column method for forming a reinforcing columnar structure made of soil cement in the ground is known (see Patent Document 1 and Patent Document 2).
In the soil cement column method, a hollow rod is inserted vertically into the ground, and cement milk is pumped into it. Further, the inside of the rod is agitated, and the ground excavated material such as earth and sand and cement milk are kneaded. Then, the rod is pulled out to leave the kneaded material and solidified to form a soil cement column in the ground.

Such a reinforcing columnar structure using a soil cement column is mainly used as a ground improvement for improving the supporting force (see Patent Document 1). Moreover, it is used also as ground improvement for improving horizontal proof stress (refer patent document 2).
In these reinforcing columnar structures, it has been proposed to dispose a steel pipe as a column core material in a soil cement column.

Aside from the strength measures described above, ground improvement includes groundwater drainage measures. In recent years, it has been attracting attention as a countermeasure against liquefaction in the ground. As such drainage countermeasures, a gravel drain method is known in which a gravel (sand gravel or crushed stone) column is formed in the ground to form a drainage structure (see Patent Document 3).
In the gravel drain method, a hollow rod is inserted vertically into the ground and filled with gravel. Then, the gravel column is formed in the ground by discharging the gravel into the ground from the lower end of the rod while pulling out the rod and solidifying it.
In such a drainage structure using a gravel column, excess water in the ground can be leached into the gravel column and discharged upward through the gap of the gravel.

JP 2007-191990 A JP 2008-25148 A JP 2008-169648 A

The above-described columnar structure for reinforcement by the soil cement column method is intended to ensure structural strength such as support force or horizontal strength, has no function of draining underground, and is not effective for liquefaction countermeasures.
On the other hand, in the drainage structure by the gravel drain construction method described above, the gravel is solidified in a column shape and has a drainage function, but does not contribute to the structural strength.
For this reason, both soil cement columns and gravel drains need to be installed when both strength measures and drainage measures (including liquefaction measures) are required for ground improvement.

However, if both the soil cement column for reinforcement and the gravel drain for drainage are installed, there is a problem that each construction work and construction cost increase.
Furthermore, even if both the soil cement column for reinforcement and the gravel drain for drainage are to be installed in the same section, there is a possibility that each of them is densely or interferes with each other, so that practical ground improvement cannot be performed.
In recent liquefaction measures, in addition to ground reinforcement, demand for a drainage function has increased, and a structure that can realize both functions has been strongly desired.

  An object of the present invention is to provide a ground improvement column capable of securing a drainage function as well as a ground reinforcement function.

The present invention is a ground improvement column embedded in the ground, which is a column main body formed of a continuous material extending from the ground surface to the ground, and a pipe body extending from the ground side end to the underground portion inside the column main body. If, have a, a communicating portion for communicating the external side of the internal and the column body of the tubular body, the tubular body and the communication unit is exposed to one of opening the ground front end of the column body The other opening is constituted by a continuous L-shaped tube exposed on the side surface of the column main body .

In the present invention as described above, the function of reinforcing the ground is obtained by the column main body formed of a continuous material (for example, soil cement). And the intensity | strength of a column main body can be increased with the pipe body (for example, steel pipe) extended inside the column main body.
On the other hand, the inside of the tubular body communicates with the outside of the side surface of the column main body through the communicating portion, and also communicates with the ground surface side end of the column main body. Therefore, when moisture in the ground has leached out to the side surface of the column main body, the moisture can be guided from the communicating portion to the surface side end of the column main body through the tube. This provides a ground drainage function.

Therefore, according to the present invention, it is possible to ensure both the ground reinforcement function and the drainage function in a single ground improvement column. As a result, it is possible to suppress the construction work and construction costs that were conventionally required for ground reinforcement and drainage, respectively, and avoid the crowding and interference of each column for ground reinforcement and drainage in the section where the ground is improved. it can.
Further, the continuous L-shaped tube can be formed by bending a steel tube, for example. And it can be set as a communicating part by arrange | positioning the short side (branch pipe) of an L-shaped pipe | tube toward the outer side from the side surface of a column main body with respect to the long side (main pipe | tube) of an L-shaped pipe | tube. Construction can be facilitated by using such an L-shaped tube.

In the present invention, it is preferable that the tube body and the communication portion include a straight pipe in which one opening is exposed at the surface side end of the column main body and the other opening is exposed at the bottom surface of the column main body .
With such a straight pipe, moisture remaining on the bottom surface of the column main body can be taken from the opening on the bottom surface and guided to the opening on the ground surface side end.

In the present invention, it is preferable that a plurality of the communication portions are installed, and that the plurality of communication portions have respective openings arranged at different heights on the side surface of the column main body.
In the present invention as described above, even when the underground water-permeable layer has a predetermined thickness and the height of the leaching moisture (underground depth) is different, moisture is taken into the communicating portion from the nearest opening. be able to.

In the present invention, it is desirable that the tubular body and the communication portion are steel pipes.
In such this invention, the intensity | strength of a pipe body and a communication part can be ensured, and the intensity | strength of the column main body for reinforcement can be raised. Moreover, since it is a general material, it is easy to secure and desirable in terms of cost.

In the present invention, the column body is preferably a soil cement column.
In the present invention, the strength as the column main body can be secured, and the earth and sand generated by excavation of the ground can be used effectively. Therefore, it is preferable in terms of material cost, and the problem of residual soil treatment can be solved.

  According to the ground improvement column of the present invention, both the ground reinforcement function and the drainage function can be secured.

Sectional drawing which shows one Embodiment of this invention. It is sectional drawing which shows the construction procedure of the said embodiment, (A) part shows the excavation process of a ground, and (B) part shows the injection | pouring process of cement milk. It is sectional drawing which shows the continuation of the construction procedure of the said embodiment, (A) part shows the embedding process of a pipe assembly, and (B) part shows the curing process of soil cement. The perspective view which shows the pipe assembly of the said embodiment. The perspective view which shows the modification of a pipe assembly. The perspective view which shows other embodiment which is not contained in this invention of a pipe | tube assembly.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
In FIG. 1, a ground improvement column 10 according to the present invention is embedded in the ground 1 in order to improve the ground.
The ground 1 has a water-permeable gravel layer 3 between layers 2 and 4 made of ordinary earth and sand. The range (upper surface depth and lower surface depth) of the gravel layer 3 is acquired in advance by performing ground investigation work such as boring.

The ground improvement column 10 has a columnar column body 11 formed of soil cement.
The column main body 11 is integrally formed by an existing soil cement column method, and continuously extends from the ground surface of the ground 1 to the ground.
A tube assembly 20 is embedded in the column main body 11.
As shown in FIG. 4, the pipe assembly 20 is formed by bundling a plurality of steel pipes, and has two types of L-shaped pipes 20A and 20B having different lengths, and a longer straight pipe 20C. .

Each of the L-shaped pipes 20A and 20B has a long main pipe 21 and a short branch pipe 22 that is bent by 90 degrees and continues to the main pipe 21 and communicates with each other.
The distal end of the main pipe 21 opposite to the branch pipe 22 is an opening 23, and the distal end of the branch pipe 22 opposite to the main pipe 21 is an opening 24.
Therefore, in the L-shaped tubes 20A and 20B, the openings 23 to 24 are communicated with each other through the main pipe 21 and the branch pipe 22, respectively.
The straight pipe 20C is entirely composed of the main pipe 21 and communicates from the opening 23 at one end to the opening 25 at the other end.

Such a tube assembly 20 is embedded in the column body 11 with the openings 23, 24, and 25 exposed on the surface of the column body 11.
That is, the openings 23 of the main pipes 21 of the L-shaped pipes 20A and 20B and the straight pipe 20C are exposed on the upper surface (end on the ground surface side) of the column main body 11.

The openings 24 of the branch pipes 22 of the L-shaped tubes 20A and 20B are exposed to the side surface of the column main body 11, and thereby the internal space of the L-shaped tubes 20A and 20B and the external space on the side surface of the column main body 11 are communicated. .
These openings 24 are arranged at different heights on the side surface of the column main body 11. In particular, the opening 24 is disposed at a depth corresponding to the gravel layer 3 acquired in advance by the ground survey work.
The opening 25 of the straight pipe 20 </ b> C is exposed on the bottom surface of the column main body 11.

In the present embodiment, the main pipe 21 of the pipe assembly 20 is the pipe body of the present invention, and the branch pipe 22 is the communication portion of the present invention.
Such a ground improvement column 10 of the present embodiment is applied to the ground 1 according to the following procedure.

As shown in FIG. 2A, first, the excavating steel pipe 31 and the excavating drill 32 are coaxially arranged on the ground surface of the ground 1 and excavated vertically downward.
As shown in FIG. 2 (B), when the excavation reaches the desired depth, the excavation drill 32 is stopped, pulled out upward, and extracted from the excavation steel pipe 31. At this time, the earth and sand 5 generated by excavation is left inside the excavation steel pipe 31.
Subsequently, the cement milk 6 is injected from the cement supply device 33 into the excavating steel pipe 31, mixed with the earth and sand 5, and stirred and kneaded.

When the soil cement 7 is generated inside the excavating steel pipe 31 as shown in FIG. 3A, the pipe assembly 20 is introduced from above the excavating steel pipe 31 and immersed in the soil cement 7 inside.
As shown in FIG. 3B, when the tube assembly 20 reaches the desired depth, the state is maintained and the solidification of the soil cement 8 is awaited. At this time, the pipe assembly 20 maintains the state in which the opening 24 of the branch pipe 22 is exposed on the side surface of the soil cement 8 and the opening 25 of the straight pipe 20C is exposed on the bottom surface of the soil cement 8.

In FIG. 3 (B), when the soil cement 8 solidified to a certain extent is obtained, the excavation steel pipe 31 is separated from the soil cement 8 by vibration or the like and pulled upward. Moreover, compressed air is sent from the opening 23 of the pipe assembly 20, and the clogging of the openings 24 and 25 exposed on the side surface or the bottom surface of the soil cement 8 is removed. In addition, the clearance gap around the soil cement 8 of the trace which extracted the steel pipe 31 for excavation is block | closed with the surrounding earth and sand.
Thereafter, the soil cement 8 is completely solidified to form the column main body 11 (see FIG. 1) in which the pipe assembly 20 is embedded.

According to this embodiment, the following effects can be obtained.
In the ground improvement column 10 of the present embodiment, the reinforcing function of the ground 1 is obtained by the column main body 11 formed of a continuous material of the soil cement 8. The strength of the column body 11 can be increased by the tube assembly 20 extending inside the column body 11.

  The tube assembly 20 is a bundle of two types of L-shaped tubes 20A and 20B and a straight tube 20C. In particular, in the longitudinal direction of the column body 11, the main tube 21 is bundled. Sufficient strength can be obtained against bending or horizontal shearing.

Further, in the tube assembly 20, the L-shaped tubes 20 </ b> A and 20 </ b> B communicate from the opening 24 on the side surface of the column body 11 to the opening 23 on the ground surface side end of the column body 11. In particular, the opening 24 on the side surface of the column body 11 is arranged according to the depth of the gravel layer 3.
Therefore, when excessive moisture leaches out from the side surface of the column main body 11 in the gravel layer 3, this moisture is taken in from the opening 24, and from the branch pipe 22 that is a communicating part of the L-shaped pipes 20A and 20B, Through a certain main pipe 21, the column main body 11 is led to the opening 23 on the ground surface side end.

Therefore, in the ground improvement column 10 of the present embodiment, in addition to the reinforcement of the ground 1, the drainage function of the ground 1 can be obtained.
As a result, it is possible to suppress the construction work and construction costs that were conventionally required for ground reinforcement and drainage, respectively, and avoid the crowding and interference of each column for ground reinforcement and drainage in the section where the ground is improved. it can.

In the present embodiment, the moisture remaining on the bottom surface of the column main body 11 can also be taken in from the opening 25 and guided to the opening 23 at the surface side end by the straight pipe 20C.
Further, in the present embodiment, since the L-shaped tubes 20A and 20B are used, the branch pipe 22 that is the communicating portion and the main pipe 21 that is the tubular body can be manufactured in a continuous state. For this reason, compared with the case where a separate pipe body and a communication part are connected etc., manufacture is easy and it is not necessary to consider the communication with a pipe body and a communication part separately.

Further, since the L-shaped tubes 20A and 20B having different lengths are used and the openings 24 are arranged at different heights on the side surface of the column main body 11, even when the gravel layer 3 is thick, moisture can be reliably obtained from the nearest opening 24. Can be captured.
Further, since the L-shaped pipes 20A and 20B and the straight pipe 20C are each formed of a steel pipe, the basic strength can be increased. In addition, the material cost can be reduced, and the material can be easily secured.

  Further, since the column body 11 is a soil cement column, it can be easily formed by excavating the ground 1 and then injecting and kneading the cement. Further, the strength as the column main body 11 can be secured, and the earth and sand generated by excavation of the ground 1 can be effectively used. Therefore, it is preferable in terms of material cost, and the problem of residual soil treatment can be solved.

Note that the present invention is not limited to the configuration of the above-described embodiment, and modifications and the like within a scope in which the object of the present invention can be achieved are included in the present invention.
In the embodiment described above, the L-shaped tubes 20 </ b> A and 20 </ b> B having different lengths are used, and the openings 24 are arranged at two different heights on the side surface of the column main body 11. On the other hand, an L-shaped tube having a different length may be added to the tube assembly 20, and the opening 24 may be arranged at three or more different heights.

On the other hand, in the pipe assembly 20, it is not essential for the present invention to install the openings 24 at a plurality of different heights, and only one height may be provided.
In FIG. 5, the tube assembly 20 is configured by bundling an L-shaped tube 20B and a straight tube 20C, and the openings 24 are arranged at the same height. Such a tube assembly 20 is the same as that described in FIG. 4 except that the L-shaped tube 20A is not provided, and the other configurations and effects are the same.

  In addition, it is not essential for the present invention to use the structure of the pipe assembly 20 with the straight pipe 20C and to form the opening 25 on the bottom surface of the column main body 11, and the straight pipe 20C is formed from the construction shown in FIG. 4 or FIG. The tube assembly 20 except for the above may be used.

In the above-described embodiment, the main tube 21 of the L-shaped tubes 20A and 20B is bundled to form the tube assembly 20. However, the tube body of the present invention is not limited to a configuration in which a plurality of tubes are bundled, and is distributed to each part of the column main body 11. You may arrange .

FIG. 6 shows another embodiment not included in the present invention.
In FIG. 6, the tube assembly 40 is embedded inside the column main body 11.
The pipe assembly 40 has three main pipes 41 formed of steel pipes as pipe bodies along the peripheral surface of the column main body 11. The main pipes 41 are connected to each other by a frame body 42 in the circumferential direction of the column main body 11.
The main pipe 41 is formed with an opening 44 facing the outside of the column main body 11 in the vicinity of the lower end, and the opening 44 communicates with the upper end (ground surface side) opening 43 through the inside of the main pipe 41.
In the present embodiment, the inside of the main building 41 and the outside of the side surface of the column main body 11 are communicated with each other through the opening 44, and the opening 44 is a communicating portion of the present invention. The main pipes 41 have different lengths, and the openings 44 are arranged at different heights.

  Also in such a tube assembly 40, the column main body 11 can be reinforced by the main pipe 41, and the opening 44 on the side surface of the column main body 11 and the opening 43 on the ground surface side are communicated with each other. Of water can be drained.

In the above-described embodiments of the present invention, the steel pipes (main pipes 21 and 41) are used as the pipe body, but other metals or other materials such as fibers can be used as long as the desired strength, that is, the reinforcing function can be obtained. A reinforced plastic or the like may be used.
In the above-described embodiment, the branch pipes 22 of the L-shaped pipes 20A and 20B are formed at right angles to the main pipe 21, but may have other angles.

  The present invention can be used as a ground improvement column.

DESCRIPTION OF SYMBOLS 1 ... Ground 2, 4 ... Geologic formation 3 ... Gravel layer 5 ... Earth and sand 6 ... Cement milk 7, 8 ... Soil cement 10 ... Ground improvement column 11 ... Column main body 20 ... Pipe assembly 20A, 20B ... L-shaped pipe 20C ... Direct Pipe 21 ... Main pipe 22 as a pipe body ... Branch pipes 23, 24 and 25 as communication portions ... Opening 31 ... Drilling steel pipe 32 ... Drilling drill 33 ... Cement supply device 40 ... Pipe assembly 41 ... Main pipe 42 ... Frame 43 ... Opening 44 ... Opening as communication part

Claims (5)

A ground improvement column buried in the ground,
A column body formed of a continuous material extending from the ground surface to the ground;
A tube extending from the surface side end to the underground part inside the column body,
Have a, a communicating portion for communicating the external side of the internal and the column body of the tubular body,
The tube body and the communication portion are constituted by a continuous L-shaped tube with one opening exposed at the surface side end of the column body and the other opening exposed at the side surface of the column body. A ground improvement column characterized by In the ground improvement column according to claim 1,
The tube body and the communication part include a straight pipe whose one opening is exposed at the surface side end of the column main body and the other opening is exposed at the bottom surface of the column main body. . In the ground improvement column according to claim 1 or 2,
A plurality of the communication portions are installed, and the plurality of the communication portions have respective openings arranged at different heights on the side surface of the column main body. In the ground improvement column according to any one of claims 1 to 3,
The ground improvement column, wherein the tubular body and the communication portion are steel pipes. In the column for ground improvement according to any one of claims 1 to 4,
A column for ground improvement, wherein the column body is a soil cement column.

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