JP2007297834A - Core material, soil cement wall, soil cement wall pile, soil cement structure, and substructure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a soil cement wall which is excellent in cost efficiency and execution performance, and which can bear a load in perpendicular direction as a part of a substructure. <P>SOLUTION: A core material 11 is provided with a plurality of H-type steels 12 and a steel member 14, and is buried in the soil cement 13 of the soil cement wall which is buried in the ground of a building. The H-type steels 12 are arranged side by side in the lateral direction, and are extended in the perpendicular direction. Studs 17 are provided on the surface of a web. Then the steel member 14 connects the H-type steels 12 to each other on both sides of the wall surface. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a soil cement wall, a soil cement wall pile, and a soil cement structure that can be used as a part of a foundation structure of a building.

  Conventionally, when constructing an underground structure of a building, a method of constructing a retaining wall on the outer periphery of the underground structure and excavating the interior surrounded by the retaining wall has been widely implemented. As the retaining walls, soil cement column walls and underground continuous walls are widely used, and these retaining walls are not removed after the building is built, but are left buried in the ground around the building. ing.

By the way, conventionally, such a retaining wall is not expected to function as a foundation. For this reason, foundation piles must be provided on the outer periphery of the building separately from the retaining wall, which is inefficient. Therefore, for example, in Patent Document 1, the lower end of the H steel core material of the soil cement column wall that is the retaining wall is formed so as to reach the support layer at the important position on the outer periphery of the building. A method of using a part as a basic structure is described.
Japanese Patent No. 2736542

  In the method described in Patent Document 1, a soil cement column is formed by burying one H-shaped steel in the center of the soil cement column wall by burying one soil for the excavation hole of the column wall of the soil cement to the support layer, Used as a substitute for foundation piles. However, in the above configuration, there is no mechanism for transmitting the building load transmitted to the H-shaped steel to the soil cement, and the soil cement column is insufficient in strength against the vertical load. It is difficult to obtain sufficient vertical and horizontal strength to bear a vertical load.

  Accordingly, an object of the present invention is to provide a soil cement wall that has good economic efficiency and workability and can bear a vertical load as a part of the foundation structure, and a core material used in these.

  The core material of the present invention is a core material used by being embedded in a soil cement wall, a soil cement wall pile, or the like, and is arranged so as to be arranged in a lateral direction, and extends in a vertical direction in which studs are provided on the surface of the web. A plurality of H-shaped steels and steel materials that connect these H-shaped steels to each other on both wall surfaces are provided. In the core material, a stud may be provided on a surface of the steel material facing the other steel material.

The soil cement wall of the present invention is a soil cement wall provided in the ground of a building, and is characterized in that the core material is embedded in the soil cement.
According to the present invention, since the high-strength soil cement is lowered with the studs embedded, the steel frame and the high-strength soil cement are integrated, and the vertical load of the building transmitted to the steel frame is transmitted via the high-strength soil cement. It can be transmitted to the support layer.

The soil cement wall of the present invention is a soil cement wall provided in the ground so as to surround a building to prevent liquefaction of the ground including a soft layer, and the core material is embedded in the soil cement. It is characterized by being. In the above-mentioned soil cement wall, at least the soft layer of the soil cement may be composed of a high-strength soil cement.
According to the present invention, by firmly restraining the soft layer surrounded by the soil cement wall, shear strain generated in the earth and sand constituting the soft ground can be suppressed and liquefaction of the ground can be prevented.

  Moreover, the soil cement wall pile of the present invention is a soil cement wall pile embedded with the above-mentioned core material, the lower end reaches the support layer, and the soil cement in the support layer is composed of a high strength soil cement. It is characterized by being.

The soil cement structure of the present invention is a soil cement structure constituted by a soil cement wall, wherein a part of the soil cement wall is constituted by the soil cement wall pile. .
Further, the soil cement structure of the present invention is a soil cement structure constituted by a soil cement wall provided in the ground so as to surround a building to prevent liquefaction of the ground including a soft layer, A part of the soil cement wall is composed of the above-mentioned soil cement wall pile, and at least the soft layer soil cement is composed of a high-strength soil cement.

  Further, in the above soil cement structure, at least a portion corresponding to the soft layer is composed of a plurality of vertically extending steel frames arranged so as to be arranged in the lateral direction, and a steel material connecting these steel frames on both sides of the wall surface. The second core member may be embedded in the soil cement.

Further, the soil cement structure of the present invention is a soil cement structure constituted by a soil cement wall provided in the ground so as to surround a building to prevent liquefaction of the ground including a soft layer, A part of the soil cement wall is composed of the above-mentioned soil cement wall pile, and at least a part corresponding to the soft layer, a plurality of vertically extending steel frames arranged in a lateral direction, and the steel walls as wall surfaces A second core member made of steel materials connected on both sides is embedded in soil cement.
In the soil cement structure, the soil cement wall may be the soil cement wall.
According to the invention, a soil cement wall can be used as part of the foundation structure. Thereby, a part of foundation pile near the perimeter of a building can be reduced, and the cost and construction period concerning construction of a foundation pile can be reduced.

  Moreover, this invention shall include the foundation structure of a building provided with said soil cement wall and a some foundation pile.

  According to the invention, a soil cement wall can be used as part of the foundation structure. Thereby, a part of foundation pile near the perimeter of a building can be reduced, and the cost and construction period concerning construction of a foundation pile can be reduced. Further, by firmly restraining the soft layer surrounded by the soil cement wall, shear strain generated in the earth and sand constituting the soft ground can be suppressed and liquefaction of the ground can be prevented.

Hereinafter, an embodiment of the soil cement wall of the present invention will be described in detail with reference to the drawings. In this embodiment, a soil cement column wall is described as an example, but the present invention can also be applied to a soil cement wall.
FIG. 1 is a horizontal sectional view showing the arrangement of the soil cement column wall 10, FIG. 2 is a sectional view taken along line II-II ′ in FIG. 1, and FIG. 3 is a sectional view taken along line III-III ′ in FIG. 4 is a cross-sectional view taken along line IV-IV ′ in FIG. The soil cement column wall 10 of this embodiment is provided on the ground having the possibility of causing liquefaction, which includes the soft layer 4 made of earth and sand and the support layer 3. As shown in FIGS. 1-4, the soil cement column wall 10 is provided so that the circumference | surroundings of the building 2 may be surrounded, and also the lower end is deeper than the soft layer 4 which may cause liquefaction. Has reached. In addition, the soil cement column wall 10 includes a wall pile portion 20 formed so that the lower end reaches the support layer 3 at an appropriate interval.

FIG. 5 is a horizontal sectional view showing a detailed configuration of the wall pile 20. As shown in the figure, the wall pile 20 is composed of a soil cement 13 and a core material 11 embedded in the soil cement 13. In the soil cement 13 constituting the wall pile portion 20, the portions corresponding to the support layer 3 and the soft layer 4 are composed of high strength soil cement 16, and the other portions are composed of ordinary strength soil cement. The high-strength soil cement 16 is formed by increasing the ratio of the cement amount to the earth and sand as compared with the normal-strength soil cement, and has a strength of about 4 [N / mm ² ] to 20 [N / mm ² ]. It is a soil cement.

  FIGS. 6A and 6B are views showing the core material 11 embedded in the wall pile 20, wherein FIG. 6A is a perspective view and FIG. 6B is a front view. As shown in the figure, the core material 11 is attached to both flange surfaces 12A of the H-shaped steel 12 so as to connect the plurality of H-shaped steels 12 arranged in the horizontal direction and extending in the vertical direction, and the plurality of H-shaped steels 12. Steel plate 14 provided. In addition, in this embodiment, although the steel plate 14 is provided so that it may extend in a horizontal direction, you may provide so that it may extend diagonally not only in this.

FIG. 7 is a view showing an H-shaped steel 12 constituting the core material 11, (A) is a perspective view, (B) is a vertical sectional view, and (C) is a front view. As shown in the figure, a stud 17 is attached to the surface of a portion corresponding to the support layer 3 of the web 12B of the H-shaped steel 12. The stud 17 may be attached to at least a portion corresponding to the support layer 3 on the surface of the web 12 </ b> B of the H-shaped steel 12, but FIG. 3 shows an example in which the stud is also provided in the ground above the support layer 3. ing.
The high-strength soil cement 16 constituting the wall pile 20 is hardened in a state where the studs 17 attached to the surface of the web 12B of the H-shaped steel 12 are embedded. For this reason, the H-shaped steel 12 and the high-strength soil cement 16 are integrated. In addition, although this embodiment demonstrated the case where the stud 17 was provided only in the web 12B of the H-shaped steel 12, you may attach not only to this but the surface of the mutually opposing side of the steel plate 17. FIG.

  A portion of the soil cement column wall 10 other than the wall pile portion 20 includes a soil cement 13 and a steel frame 18 embedded in the soil cement 13. The portion of the soil cement other than the wall pile 20 is formed of a high strength soil cement 16 at a depth corresponding to the soft layer 4 and the other portion is formed of a normal strength soil cement.

A normal soil cement column wall is formed by mixing and agitating the excavated soil generated by excavating the ground and the cement milk ejected from the tip of the excavator to form a soil cement, and before the soil cement hardens, Is constructed by inserting
When the wall pile portion 20 of the soil cement column wall 10 of the present embodiment is constructed, the earth and sand excavated while excavating the portion corresponding to the soft layer 4 and the cement milk are mixed and stirred. Increase the amount of cement to be mixed. Thereby, it can construct | assemble by making the soil cement of the part corresponded to the soft layer 4 into the high strength soil cement 16. FIG. Moreover, also when using the high intensity | strength soil cement 16 at the wall pile part 20 front-end | tip, the amount of cement mixed with earth and sand should just be increased similarly in the wall pile part 20 lower end. In addition, the core material 11 embedded in the soil cement column wall 10 is previously attached with a stud 17 to the web 12B of the H-shaped steel 12 on the ground, and a plurality of H-shaped steels 12 are connected by the steel plate 14, and this is used. What is necessary is just to insert in the soil cement 13.

  Here, the flow of force in the wall pile 20 will be described. The load of the building 2 is transmitted vertically downward to the H-shaped steel 12 of the core 11 of the wall pile 20. As described above, since the H-shaped steel 12 is integrated with the high-strength soil cement 16 by the stud 17, the building load transmitted to the H-shaped steel 12 is transmitted to the high-strength soil cement 16 through the stud 17. Is done. Further, since the high-strength soil cement 16 reaches the support layer 3, the load of the building 2 is transmitted from the high-strength soil cement 16 to the support layer 3.

  As described above, the soil cement column wall 10 of the present embodiment includes the wall pile portion 20 reaching the support layer 3, and the H-shaped steel 12 embedded in the wall pile portion 20 is connected to the high strength soil cement 16 by the stud 17. Since they are integrated, the load of the building 2 can be transmitted to the support layer 3 in the same manner as the foundation pile.

As explained above, according to the soil cement column wall 10 of this embodiment, since the vertical load of the building 2 can be transmitted to the support layer 3 similarly to the foundation pile, it can be used as a part of the foundation structure. it can. Hereinafter, the foundation structure using the soil cement column wall 10 of this embodiment is demonstrated.
FIG. 8 is a cross-sectional view showing a conventional basic structure 30 as a comparative example. Moreover, FIG. 9 is a figure which shows the foundation structure 40 using the soil cement pillar row wall 10 of this embodiment. As shown in FIG. 8, in the conventional foundation structure 30, foundation piles 31 are provided at predetermined intervals, and the vertical load of the building 2 is transmitted to the support layer 3 only by these foundation piles 31. .

  On the other hand, as shown in FIG. 9, the foundation structure 40 of this embodiment includes a soil cement column wall 10 on the outer periphery of the building 2 in addition to the foundation pile 41. As described above, the wall pile portion 20 of the soil cement column wall 10 can transmit the vertical load of the building 2 to the support layer 3. Therefore, in the conventional foundation structure 30, the load piled on the foundation pile 31 near the outer periphery of the building 2 can be loaded on the wall pile portion 20 of the soil cement column wall 10, so The foundation pile 41 can be omitted.

Thus, according to the foundation structure 40 provided with the soil cement column wall 10 of the present embodiment, foundation piles in the vicinity of the outer periphery can be omitted, so that the cost can be reduced and the construction period can be shortened. Naturally, when root cutting is performed, the soil cement column wall 10 can be excavated using the soil cement column wall 10 as a retaining wall. Therefore, since the mountain retaining wall which is temporary can be reused, the construction cost can be reduced.
Further, as described above, the soil cement column wall 10 of the present embodiment has the high strength soil cement 16 disposed at a depth corresponding to the soft layer 4, and the soft layer 4 surrounded by the soil cement column wall 10. Therefore, the shear strain of the soft layer 4 due to the earthquake motion can be reduced, and liquefaction can be prevented. Since the soil cement column wall 10 can reduce the cost required for construction compared to an underground continuous wall conventionally used as a countermeasure for liquefaction, the cost can be reduced.

In addition, although this embodiment demonstrated the case where this invention was applied to the ground containing the soft layer 4 which has a possibility of causing liquefaction, the soil cement wall of this invention can also be used for normal ground, and this In this case, a wall pile portion that reaches the support layer is provided on the soil cement wall, the soil cement in the support layer of the wall pile portion is made of high-strength soil cement, and the above-described core material may be embedded. By setting the soil cement wall in this way, it can be used as a part of the foundation.
In the present embodiment, the case where the core material is embedded in the wall pile portion of the soil cement column wall has been described. However, the lower end reaches the support layer, and the soil cement in the support layer is composed of high-strength soil cement. The core material may be embedded in the soil cement column wall pile or the soil cement wall pile. According to the soil cement column wall pile and the soil cement wall pile having such a configuration, the building load transmitted to the H-shaped steel can be transmitted to the support layer in the same manner as the wall pile portion of the present embodiment.

Further, in the soil cement column wall 10 of the above embodiment, the soil cement 13 at a depth corresponding to the soft layer 4 is composed of the high-strength soil cement 16. A second core member composed of a plurality of H-shaped steels arranged in the lateral direction and steel plates that connect the plurality of H-shaped steels to each other is embedded in a portion corresponding to the soft layer of soil cement that constitutes the column wall. It is good also as composition to do. According to such a configuration, by tying a plurality of H-shaped steels in the horizontal direction, the plurality of H-shaped steels are united to bear the horizontal shearing force due to the seismic motion, so that the proof strength against the horizontal shearing force can be increased. . For this reason, like the above embodiment, the shear strain of the soft layer due to the earthquake motion can be reduced and liquefaction can be prevented. Moreover, it is good also as a structure which embeds the core material of the structure similar to embed | buried in the wall pile part in the site | part corresponded to the soft layer of the soil cement which comprises a soil cement column wall.
Further, a portion corresponding to the soft layer of soil cement constituting the soil cement column wall is composed of high-strength soil cement, and a core material having the same structure as that embedded in the second core material or the wall pile portion. It is good also as a structure which embeds.

  In the above description, the case where the wall pile portion is provided on the soil cement column wall has been described, but not limited thereto, the wall cement portion is not provided, and the soil cement column wall is configured in the soil cement constituting the soil cement column wall. It is good also as a structure which embeds the core material mentioned above. In the above description, the soil cement in the soft layer and the support layer is composed of high strength soil cement. However, the present invention is not limited to this, and at least a part of the soil cement column wall is composed of high strength soil cement. It only has to be.

It is horizontal direction sectional drawing which shows arrangement | positioning of the soil cement pillar row wall of this embodiment. It is II-II 'sectional drawing in FIG. FIG. 3 is a sectional view taken along line III-III ′ in FIG. 1. It is IV-IV 'sectional drawing in FIG. It is sectional drawing which shows the structure of a wall pile part. It is a figure which shows the core material embed | buried under a wall pile part, (A) is a perspective view, (B) is a front view. It is a figure which shows the H-shaped steel used for the core material, (A) is a perspective view, (B) is sectional drawing, (C) is a front view. It is sectional drawing which shows the conventional basic structure. It is sectional drawing which shows the basic structure of this embodiment.

Explanation of symbols

2 Building 3 Support layer 4 Soft layer 10 Soil cement column wall 11 Core material 12 H-shaped steel 13 Soil cement 14 Steel plate 16 High strength soil cement 17 Stud 18 Steel 20 Wall pile 30 Conventional foundation structure 31 Foundation pile 40 Foundation structure 41 Foundation pile

Claims (12)

A core material used embedded in soil cement wall or soil cement wall pile,
A core comprising: a plurality of H-shaped steels arranged in a lateral direction and extending in a vertical direction with studs provided on a surface of a web; and steel materials for connecting these H-shaped steels to each other on both wall surfaces. Wood.   The core material according to claim 1, wherein a stud is provided on a surface of the steel material facing the other steel material. A soil cement wall installed in the ground of the building,
A soil cement wall in which the core material according to claim 1 or 2 is embedded in a soil cement. A soil cement wall provided in the ground so as to surround the building to prevent liquefaction of the ground including the soft layer,
A soil cement wall in which the core material according to claim 1 or 2 is embedded in a soil cement. A soil cement wall according to claim 4,
A soil cement wall, characterized in that at least a soft cement cement is composed of a high strength soil cement. A soil cement wall pile embedded with a core material according to claim 1 or 2,
A soil cement wall pile characterized in that the lower end reaches the support layer and the soil cement in the support layer is composed of high-strength soil cement. A soil cement structure constituted by a soil cement wall,
A soil cement structure, wherein a part of the soil cement wall is constituted by the soil cement wall pile according to claim 6. A soil cement structure constituted by a soil cement wall provided in the ground so as to surround a building to prevent liquefaction of the ground including a soft layer,
A part of the soil cement wall is composed of the soil cement wall pile according to claim 6,
A soil cement structure characterized in that at least a soft cement cement is composed of a high strength soil cement. A soil cement structure according to claim 8,
A second core member comprising a plurality of vertically extending steel frames arranged so as to be arranged in the lateral direction at least in a portion corresponding to the soft layer, and a steel material connecting these steel frames on both wall surfaces is provided in the soil cement. A soil cement structure characterized by being embedded. A soil cement structure constituted by a soil cement wall provided in the ground so as to surround a building to prevent liquefaction of the ground including a soft layer,
A part of the soil cement wall is composed of the soil cement wall pile according to claim 6,
A second core member comprising a plurality of vertically extending steel frames arranged so as to be arranged in the lateral direction at least in a portion corresponding to the soft layer, and a steel material connecting these steel frames on both wall surfaces is provided in the soil cement. A soil cement structure characterized by being embedded. A soil cement structure according to claim 7,
A soil cement structure comprising the soil cement wall according to claim 4 or 5. A foundation structure of a building comprising the soil cement structure according to claim 7 and a plurality of foundation piles.