JP5690864B2 - Construction method of mountain retaining wall, construction method of cast-in-place pile - Google Patents

Description

  The present invention relates to a method for constructing a retaining wall used when a cast-in-place pile is constructed in a narrow site and a method for constructing a cast-in-place pile in a narrow site.

  Conventionally, when constructing cast-in-place piles in a narrow site, the deep foundation method has been used. In the deep foundation method, the ground is excavated in a cylindrical shape by human power or a small excavator, and arc-shaped liner plates are connected in the circumferential direction and the vertical direction along the hole wall surface as the excavation progresses. The liner plate supports the surrounding ground and can prevent the ground from collapsing (see, for example, Patent Document 1 and Non-Patent Document 1).

Japanese Unexamined Patent Publication No. 6-33682

Edited by the Building Construction Law Editing Study Group, “Latest Building Construction Encyclopedia”, first edition, Industry Research Association Encyclopedia Publishing Center, July 15, 2004, p. 153-155

  By the way, in the method using the liner plate, it is necessary to inject grout or the like on the back side of the liner plate in order to close the gap with the ground. Further, in a place where the groundwater level is high, it is necessary to inject the chemical solution into the ground in advance to improve the ground, which requires labor and cost.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a method for constructing a pile in a narrow site without labor and cost.

A method for constructing a retaining wall according to the present invention is a method for constructing a retaining wall for excavating the ground in a state in which a borehole is filled with a stabilizing liquid in order to construct a cast-in-place pile by the TBH method. In the position corresponding to the outer periphery of the plurality of soil cement columns, by drilling and stirring, the lower end reaches a depth lower than the groundwater level , does not reach the depth corresponding to the lower end of the cast-in-place pile , overlapping the soil cement pillar, where adjacent, characterized by constructing a soil cement wall by building to Rukoto to be coupled to a ring.

Moreover, the method for constructing a cast-in-place pile by the TBH method of the present invention includes a soil cement wall constructing step for constructing a soil cement wall by the above-described method for constructing a retaining wall, and a lower end of the cast-in-place pile through the interior of the soil cement wall A ground excavation step for forming the excavation hole by excavating the ground in a state where the excavation hole is filled with a stabilizing liquid to a depth corresponding to the above, a rebar cage arrangement step for arranging a rebar cage in the excavation hole, and the excavation A concrete placing step for placing concrete in the hole.

  According to the present invention, a soil cement wall is formed by connecting soil cement pillars in an annular shape, and the inside of the soil cement wall is excavated to form a drilling hole. Cost can be reduced. Moreover, since the soil cement wall has a water-stopping property, it is possible to prevent underground water from penetrating into the excavation hole.

It is the figure (the 1) for demonstrating the construction method of a cast-in-place pile, (A) is a vertical sectional view, (B) is II sectional drawing in the same figure (A). It is a figure (the 2) for demonstrating the construction method of a cast-in-place pile, and is a vertical sectional view. It is a figure (the 3) for demonstrating the construction method of a cast-in-place pile, and is a vertical sectional view. It is a figure (the 4) for demonstrating the construction method of a cast-in-place pile, and is a vertical sectional view. It is a figure for demonstrating the method to construct | assemble a soil cement wall. It is a figure which shows the rotary excavation blade of the excavator used when building a soil cement wall. It is a figure for demonstrating the method to construct | assemble a soil cement wall, (A1) and (B1) are top views, (A2) and (B2) are figures which expand and show a vertical cross section. It is a top view which shows the soil cement wall for constructing the cast-in-place pile constructed | assembled by the method of another embodiment.

  Hereinafter, an embodiment of a method for constructing a cast-in-place pile according to the present invention will be described by taking as an example a case where a cast-in-place pile is constructed in a narrow site of an existing railway station. In this embodiment, it is assumed that the groundwater level is higher than the lower end of the cast-in-place pile.

1-4 is a figure for demonstrating the construction method of the cast-in-place pile of this embodiment. 1A and 2 to 4 are vertical cross-sectional views, and FIG. 1B is a cross-sectional view taken along the line II in FIG.
First, as shown in FIG. 1, a cylindrical soil cement wall 10 is constructed around the construction position of a cast-in-place pile. The soil cement wall 10 is formed by connecting a plurality of cylindrical soil cement columns 11 in an annular shape. These soil cement columns 11 are such that the distance between the centers of the adjacent soil cement columns 11 is smaller than the diameter of the soil cement columns 11, and both side portions of each soil cement column partially overlap the adjacent soil cement columns 11. Has been built. Moreover, the soil cement wall 10 has reached the depth where the lower end is lower than the groundwater level.

  As the soil cement pillar 11, for example, when a cast-in-place pile having a diameter of about 2500 mm is constructed, the diameter may be about 600 mm. Further, as will be described later, when a compressive load acts on the soil cement wall 10 from the surrounding ground, adjacent soil cement columns 11 can be transmitted between the soil cement columns 11. The width of the overlapping portions (D in FIG. 5B) may be, for example, about 150 mm. However, the diameter of the soil cement pillar 11 and the width of the overlapping portion are not limited to these.

Hereinafter, the construction method of the soil cement wall 10 will be described.
FIG. 5 is a view for explaining a method of constructing the soil cement wall 10. First, as shown in FIG. 5A, every other soil cement column 11 constituting the soil cement wall 10 is constructed. The soil cement pillar 11 includes, for example, a rod having a drilling blade for excavating the ground at the tip, and a boring machine capable of discharging cement milk from the tip of the rod, and excavating the ground by the boring machine. After forming the cylindrical excavation hole, it can be constructed by discharging the cement milk from the tip of the rod into the excavation soil while mixing and stirring the excavation soil and the cement milk while pulling up the rod while rotating.
In this embodiment, the ground is rotated and stirred by rotating the excavating blade and rotating the ground. However, the present invention is not limited to this. The excavating blade is rotated and the excavating blade is vibrated up and down. The ground may be stirred by drilling, or the ground may be stirred by spraying water or cement milk downward. Furthermore, these methods may be combined, and the method of stirring and drilling the ground may be appropriately selected according to the ground conditions.

Next, as shown in FIG. 5 (B), a soil cement column 11B is newly constructed between the soil cement columns 11A constructed with a gap. In addition, when excavating the ground to newly construct the soil cement pillar 11B, the side part of the adjacent soil cement pillar 11A that has already been constructed is cut. And the adjacent soil cement pillars 11 are connected by mixing and stirring cement milk with excavated soil in the excavation hole. In addition, when cutting the side portion of the soil cement pillar 11A, if it is difficult to apply the method of rotating the excavation blade because the soil cement is hard, the above-described method of vibrating the excavation blade up and down, A method of spraying water or cement milk toward the surface may be used in combination.
In addition, as shown in FIG. 1, when the upper end part of the soil cement pillar 11 is lower than the ground surface, in order to protect a hole wall surface, you may attach the cyclic | annular liner plate 12 to the upper part of the soil cement pillar 11. .

  After the annular soil cement wall 10 is constructed in this way, as shown in FIG. 2, the ground is excavated to a predetermined depth inside the soil cement wall 10 by the excavator 20 to form the excavation hole 13. As the excavator 20, an excavator that can excavate even in a narrow site, for example, used in the TBH method is suitable. At this time, the inside of the excavation hole 13 is filled with the stabilizing liquid, but since the soil cement wall 10 surrounds the excavation hole 13 and the soil cement wall 10 has a water-stopping property, the stabilizing liquid is surrounded by To prevent leakage. That is, when there is an underground structure around the site where the cast-in-place pile 30 is to be constructed, if the stable liquid leaks from the excavation hole 13, the stable liquid may enter the underground structure. However, this embodiment can prevent this. Moreover, since the soil cement wall 10 has a water-stopping property, it is possible to prevent the groundwater from seeping out.

  When excavating the ground 1, soil water pressure acts on the soil cement wall 10 from the surrounding ground 1. However, since the soil cement wall 10 is formed in an annular shape, it resists this soil water pressure due to the ring compression effect. Can do. Moreover, since the soil cement wall 10 has a water-stopping property, it can prevent that groundwater oozes out inside.

Next, as shown in FIG. 3, a rebar cage 14 is built in the excavation hole 13. In addition, it is good to connect the reinforcement | strengthening cage | basket | car 14 previously, what was divided | segmented into the length direction is built.
Next, as shown in FIG. 4, the tremy pipe 21 is inserted into the excavation hole 13, and the concrete 15 is placed in the excavation hole 13 through the tremy pipe 21. Construction of the cast-in-place pile is completed when the placed concrete 15 is hardened.

  According to the present embodiment, by connecting the soil cement pillars 11 in an annular shape, the ground can be supported by resisting soil water pressure due to a ring compression effect, and the soil cement pillars 11 are lower than the groundwater level at the lower end. In addition, it is possible to prevent underground water from penetrating into the excavation hole 13 from the surrounding ground 1 and to fill the excavation hole 13 with the stabilizing liquid. Can prevent seepage.

  In addition, in the conventional method of supporting the ground by connecting the liner plates, it is necessary to perform a chemical solution injection operation, a liner plate installation operation, and a grout injection operation on the ground, which is troublesome and costly. However, in the present embodiment, it is only necessary to construct the soil cement pillar 11 in an annular shape, so that labor and cost for construction can be reduced.

  Moreover, since the soil cement wall 10 can bear a vertical load, the soil cement wall 10 can also function as a pile, and when the soil cement wall 10 is integrated with the cast-in-place pile 30, the cast-in-place pile 10 The vertical supporting force can be improved. Further, if a core material such as H-shaped steel or steel pipe is embedded in all or some of the soil cement pillars 11 constituting the soil cement wall 10, the strength of the soil cement wall 10 is improved and cast in place. The supporting force of the pile 30 is further improved.

  In the present embodiment, the soil cement columns 11 are connected to each other by constructing the soil cement columns 11 so that the end portions thereof overlap with the adjacent soil cement columns 11. Is not limited to this.

Hereinafter, another embodiment in which the connecting method of the soil cement pillar 11 is different will be described.
In the present embodiment, as shown in FIG. 6, an excavator 200 in which a rotary excavation blade 100 is attached to the tip of a rod 110 is used. The excavator 200 is configured to be able to switch between a state in which cement milk pumped from the ground is sprayed downward from the lower part of the rotary excavation blade 100 and a state in which the cement milk is injected laterally from the tip of the rotary excavation blade 100. . Further, the excavator 200 can limit the range in which the cement milk is jetted from the tip of the rotary excavating blade 100 to the side by limiting the rotation angle of the rod 110 to a predetermined angle range.

  FIG. 7 is a view for explaining a method of constructing a soil cement wall using such an excavator, (A1) and (B1) are plan views, and (A2) and (B2) are enlarged vertical sections. FIG. First, as shown in FIGS. 7 (A1) and (A2), the rotary excavation blades 100 are entirely disposed in a state where cement milk is sprayed downward from the rotary excavation blades 100 at predetermined intervals in the horizontal direction. The cylindrical excavation hole 120 is formed by rotating the circumference. Thereby, the excavated soil in the excavation hole 120 and the cement milk are mixed and stirred, and the soil cement pillar 130 can be constructed. The interval between the excavation holes 120 is an interval at which a connecting portion 141 connecting the excavation holes 140 and the excavation holes 120 described later can be excavated between the excavation holes 120.

  Next, as shown in FIG. 7 (B1), excavation holes 140 are formed between the soil cement pillars 130 formed in the above process. At this time, first, as in the case of the excavation hole 120 described with reference to FIG. 7A2, the rotary excavation blade 100 is rotated all around in a state where cement milk is jetted downward from the rotary excavation blade 100. Then, the ground is excavated to a predetermined depth.

  Next, as shown in FIG. 7 (B2), the cemented milk is switched to a state of spraying from the tip of the rotary excavation blade 100 to the side, and the rod 110 is repeatedly reciprocated within a predetermined angular range to rotate the rotary excavation blade. The rotary excavation blade 100 is lifted up while swinging 100. As a result, as shown in FIG. 7 (B1), the portion of the ground where the cement milk is injected between the adjacent soil cement pillars 130 is excavated into a fan shape corresponding to the swing range of the rotary excavating blade 100 (hereinafter referred to as “swing”). The fan-shaped portion is referred to as a connecting portion 141), and a part of the outer peripheral surface of the adjacent soil cement pillar 130 is exposed. In addition, the angle range (namely, rotation range of the rod 110) which rocks the rotary excavation blade 100 acts between the adjacent soil cement pillars 130 and 131 by the soil cement 132 constructed | assembled in the connection part 141 so that it may mention later. What is necessary is just to install so that it may have a width | variety which can transmit a compressive load.

Moreover, by excavating the cement part 141 by jetting cement milk as described above, the excavated soil and the cement milk in the connector part 141 are mixed and stirred, and the soil cement 132 is formed in the connector part 141. . As a result, as shown in FIG. 8, the soil cement pillar 131 is constructed in the excavation hole 140, and the adjacent soil cement pillars 130 and 131 are connected by the soil cement 132 of the connecting portion 141, A soil cement wall 150 in which the soil cement columns 130 and 131 are connected in an annular shape is constructed. Thus, by connecting the cylindrical soil cement columns 130 and 131 in a ring shape, it is possible to resist the soil water pressure acting from the surrounding ground similarly to the above-described embodiment by the ring compression effect. Moreover, since the soil cement pillars 130 and 131 are connected by the soil cement 132 of the connecting portion 141, the soil cement pillars 130 and 131 are stable when flowing into the groundwater from the surrounding ground or excavating the portion corresponding to the cast-in-place pile. The liquid can be prevented from oozing out to the surrounding ground.
And the cast-in-place pile can be constructed by excavating the inside of the soil cement wall 150 as in the first embodiment.
Also according to this embodiment, similarly to the first embodiment, it is possible to reduce labor and cost for construction compared to a conventional method of connecting a liner plate and supporting the ground.

  In the second embodiment, when excavating the excavation hole 140, cement milk is jetted downward from the rotary excavation blade 100, and when excavating the connection portion 141, the tip of the rotary excavation blade 100 is laterally moved. However, the present invention is not limited to this, and water or a stable liquid may be jetted from the rotary excavation blade 100. In such a case, after excavating the excavation hole 140 and the connecting portion 141, the cement milk is poured into the excavation hole and the excavation hole 140 and A soil cement may be constructed in the connecting portion 141.

  In the second embodiment, as an excavator, an apparatus capable of switching between a state in which cement milk is jetted downward from the rotary excavation blade 100 and a state in which cement milk is jetted laterally from the tip of the rotary excavation blade 100 is used. However, the present invention is not limited to this, and it is sufficient that the cement milk can be sprayed at least to the side. In this embodiment, cement milk is sprayed downward from the entire rotary excavation blade 100, but only the center or the periphery may be used.

  In the second embodiment, the excavation hole 140 is drilled by rotating the rotary excavation blade 100 and jetting cement milk downward from the rotary excavation blade 100. However, the present invention is not limited to this. As a method for drilling, the method of rotating the rotary excavating blade 100, the method of applying vibration in the vertical direction of the rotary excavating blade 100, and the method of spraying cement milk downward may be appropriately combined.

  In the second embodiment, first, the rotary excavating blade 100 is lowered while rotating to form the excavation hole 120, and the cement milk is jetted from the tip of the rotary excavating blade 100 to the side and is swung. However, it is decided to excavate a portion corresponding to the ground connecting portion 141 by pulling upward, but not limited to this, the rotary excavating blade 100 is swung and the cement milk is sprayed from the tip sideward while moving downward. The excavation hole 120 and the connection part 141 may be excavated by lowering.

  Further, in the second embodiment, the rotary excavation blade 100 is swung while jetting cement milk from the tip of the rotary excavation blade 100 to the side, thereby excavating the connecting portion 141 and forming the cement milk. Although the cement columns 130 and 131 are connected, the method of connecting the soil cement columns 130 and 131 is not limited to this. For example, a small-diameter soil cement column is constructed between the soil cements 130 and 131 so that the sides of the soil cements 130 and 131 overlap with each other, and the soil cement columns 130 and 131 are connected by the small-diameter soil cement columns. May be.

  Moreover, although each said embodiment demonstrated the case where a cast-in-place pile was built in the existing station, it is suitable if it is the case where not only this but a cast-in-place pile is constructed in a narrow site.

  Further, in the above embodiment, the work of excavating the portion corresponding to the cast-in-place pile of the ground is performed using the excavator 20, but not limited to this, the worker enters the excavation hole 13 and performs it. Also good. At this time, an annular soil cement wall 30 is constructed around the periphery, and the soil cement wall 30 has a water-stopping property, so that intrusion of groundwater into the excavation hole 13 can be prevented.

  In addition, the present invention is not necessarily limited to a place where the groundwater level is higher than the lower end of the cast-in-place pile, and can also be applied in construction where the groundwater level is lower than the lower end of the cast-in-place pile. Can save time and money.

DESCRIPTION OF SYMBOLS 10 Soil cement pillar 11 Soil cement wall 12 Liner plate 13 Excavation hole 15 Concrete 20 Excavator 21 Tremy pipe 30 Cast-in-place pile 40 Anchor bolt 41 Steel pillar 100 Rotary excavation blade 110 Rod 120, 140 Excavation hole 130, 131 Soil cement pillar 132 Soil cement 141 Fan section 150 Soil cement wall

Claims (2)

A method for constructing a retaining wall for excavating the ground in a state where the inside of the excavation hole is filled with a stabilizing liquid in order to construct a cast-in-place pile by the TBH method ,
At a position corresponding to the outer periphery of the cast-in-place pile, a plurality of soil cement columns are drilled and stirred, so that the lower end reaches a depth lower than the groundwater level, and at a depth corresponding to the lower end of the cast-in-place pile. not reach overlaps the soil cement pillar, where adjacent, earth retaining wall construction method of which is characterized by building a soil cement wall by building to Rukoto to be coupled to a ring. It is a construction method of cast-in-place piles by TBH method ,
A soil cement wall construction step of constructing a soil cement wall by the method of constructing a retaining wall according to claim 1 ;
A ground excavation step for excavating the ground in a state where the inside of the excavation hole is filled with a stabilizing liquid to a depth corresponding to the lower end of the cast-in-place pile through the inside of the soil cement wall, and forming the excavation hole;
A rebar cage placement step for placing a rebar cage in the borehole;
A method for constructing a cast-in-place pile, comprising: a concrete placing step for placing concrete in the excavation hole.

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