KR20110052321A - Steel pipe pile for sheet pile wall and construction method using that - Google Patents

Abstract

PURPOSE: A steel pipe pile for a retaining wall and a construction method of a retaining wall using the same are provided to secure stable supporting force by embedding the front end of the steel pipe pile in the ground. CONSTITUTION: A construction method of a retaining wall using a steel pipe pile for a retaining wall is as follows. Multiple excavation holes are formed by excavating the ground using an auger, and cases are inserted into the excavation holes. Steel pipe piles(100) are inserted into the excavation holes. A concrete layer is formed by placing concrete in the inner bottom of the excavation holes. The concrete layer is cured by upward extracting and eliminating the cases. Soil retaining plates(200) are inserted into guiderails(160) of the steel pipe piles. The top ends of the steel pipe piles are connected to each other using a connection member(300).

Description

Steel pipe pile for sheet pile wall and construction method using that}

The present invention relates to a pile file, and more particularly, in the construction and excavation of civil engineering work, steel pipe piles and installed using the same to prevent the soil and ground of the edge collapse or sink down It is about earthen construction method.

In general, in order to build underground structures such as basement of the building or subway, the construction of a trench having a depth below the ground is carried out, and a protective wall is installed to prevent the soil wall from falling down due to earth pressure during the construction of the trench. In addition, the leveling work should be performed in parallel to prevent the groundwater from the ground flowing into the construction area.

The cladding construction should be designed to withstand the working load with sufficient strength and rigidity as a means to secure the trench. Such construction of the wall construction can be divided into the strut and earth anchor method. In addition, excavation by Soil Nailing method or Raker support method is used. In rock area, Rock Bolt is used instead of Earth Anchor.

In this case, the reinforcement method is widely used in the excavation work below the medium scale where the gap between the wall walls is not large, and the middle pile (Post Pile) should be constructed to prevent the buckling of the reinforcement beam. This method can be applied regardless of the type of strata, and it is easy to reinforce even if deformation occurs in the wall during excavation.

As shown in FIG. 1, the structure of the general bracing structure is a plurality of H-type steels along the edge of the trench area at predetermined intervals to a predetermined depth in the ground, and then the depth is lowered from the inner region to the lower side of the ground. To carry out the digging work. The earthen board structure is installed by inserting a wooden earth plate (2) between the H-shaped steels (1) arranged at regular intervals to prevent the earth or sand from flowing into the workplace by the earth pressure. The earth plate (2) proceeds with the trench construction in such a way that the additional insertion between the H-type steel (1) as the trench construction proceeds from the inside of the earthenware structure.

As the conventional earthenware structure as described above, the general H-type steel (1) is mainly used, the strong load acts to the inside by the earth wall of the cut out as the trench construction proceeds to a predetermined depth. This load is transmitted as it is to the H-shaped steel (1) functioning as a reinforcing function, the H-shaped steel (1) of the earthquake construction according to the prior art is simply installed in the ground, the strong bearing capacity only by the H-shaped steel (1) itself There is a problem that cannot be secured.

In order to solve this problem, the reinforcement 3 should be further constructed inside the H-shaped steel 1 as shown. However, such a reinforcement (3) is rather a big obstacle in the construction area, as the work space becomes narrow, which causes the difficulty of the work, thereby increasing the risk of accidents.

The earth block structure of the H-type steel according to the prior art can not secure a stable support force, there is a problem to make the construction work difficult to complicate the structure of the work space when the reinforcement is further constructed.

Therefore, the present invention has been proposed to solve the above problems, while providing a stable support force using the seismic steel pipe piles, providing a steel pipe pile for the mud can be easily made construction works and a mud wall construction method using the same. It aims to do it.

Steel pipe pile for the mudstone of the present invention for achieving the above object is a hollow cylindrical steel pipe; At least two ribs fixed radially outside the tip of the steel pipe; A donut-shaped expansion plate fixed to a bottom end of the steel pipe and a bottom of the rib; And 'b'-shaped or' c'-shaped guide rails symmetrically fixed to each other on the outside of the steel pipe, wherein the ribs and the lower buried portion of the steel pipe to which the expansion plate is fixed are fixed by a concrete layer in the ground. To the guide rail, the earth plate is sequentially inserted sliding, characterized in that the plurality of the upper end of the steel pipe is configured to be connected to each other by a connecting member.

In addition, the soil construction method using a steel pipe pile according to an embodiment of the present invention comprises the steps of excavating the ground using an auger inserted into the case at regular intervals along the edge of the trench region to form a plurality of excavation holes; Ribs are radially fixed to the outside of the hollow cylindrical steel pipe tip portion inside the excavation hole, a donut-shaped bearing expansion plate is fixed to the bottom of the rib, 'b' shape or 'c' shape on the outside of the upper end of the steel pipe Inserting a steel pipe pile having a guide rail symmetrically fixed thereto; Placing concrete on an inner lower portion of the excavation hole to form a concrete layer; Removing the case while extracting the upper portion, and curing the concrete layer; Inserting the earth plate into the guide rail of the steel pipe pile as the trench proceeds; And connecting the plurality of steel pipe pile tops to each other using a connection member.

By using the seismic resistant steel pipe piles configured as described above, the tip end portion of the steel pipe pile is deeply embedded in the ground to ensure stable supporting force. In addition, a separate reinforcing brace is not constructed, the structure can be simplified, thereby exhibiting the effect that the operation can be performed smoothly.

The technical problems achieved by the present invention and the practice of the present invention will be more clearly understood by the preferred embodiments of the present invention described below. The following examples are merely illustrated to illustrate the present invention and are not intended to limit the scope of the present invention. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

According to an exemplary embodiment of the present invention, the earthquake construction purchases the tip portions of the plurality of earthquake-resistant steel pipe piles 100 to a depth deep into the ground, and guides the earth plate 200 of the steel pipe piles 100 according to the excavation construction. ) Into the process of insertion.

Figure 2 is a perspective view showing a steel pipe pile according to an embodiment of the present invention, Figure 3 is a partial cross-sectional view showing a steel pipe pile according to an embodiment of the present invention, Figure 4 is a underground penetration of the steel pipe pile according to an embodiment of the present invention Some sectional drawing which showed the state.

2 to 4, the steel pipe pile 100 according to an embodiment of the present invention is fixed to the rib 120, the bottom surface of the rib 120 is fixed to the outer end of the circular column-shaped steel pipe 110. It is composed of a seismic pile comprising an expansion plate 130 that is.

Looking at this in more detail, the above-described steel pipe 100 is configured to support the load from the upper side, is formed in a hollow cylindrical shape having a predetermined diameter (Φ 1). The general steel pipe pile is composed of a steel pipe of a diameter smaller than the diameter of the excavation hole (2), but the seismic pile is composed of a relatively small diameter steel pipe with a large difference from the diameter of the excavation hole (2), the steel pipe 110 ) And the excavation hole wall has a wide gap, so it is possible to insert the tremis tube so that concrete can be easily placed.

The above-described rib 120 is provided with a plurality of fixed to the outer end of the steel pipe 110 by welding, and is fixed radially with respect to the steel pipe 110 and its bottom surface is consistent with the bottom surface of the steel pipe (110).

The rib 120 supports the expansion plate 130 with respect to the steel pipe 110, and is embedded in the concrete layer formed by placing concrete in the lower portion of the excavation hole during the construction of the embedded pile.

The above-described expansion plate 130 is a donut-shaped disk, which is fixed to the bottom of the rib 120 by welding, the inner diameter of which matches the inner diameter of the steel pipe 110, and the outer diameter Φ 2 is larger than the outer diameter of the steel pipe 110. Smaller than the inner diameter of the excavation hole (2) is formed smaller.

As such, the expansion plate 130 is firmly fixed to the front end of the steel pipe 110 and the outer diameter is formed larger than the outer diameter of the steel pipe serves to enlarge the diameter of the front end of the steel pipe.

Therefore, the gap formed between the side wall of the steel pipe 110 and the excavation hole 2 when the steel pipe pile 100 is inserted into the excavation hole is compared with the case where the expansion plate is not provided with the steel pipe 110 and the excavation hole ( Since the gap formed by the side wall of 2) becomes narrower, the bearing capacity of the tip of the steel pipe increases accordingly.

In addition, the steel pipe pile 100 having the structure as described above is a steel pipe 110 of a relatively small diameter (Φ1) by the rib 120 and the expansion plate 130 provided at the front end of the steel pipe 110, compared to the prior art. Even if configured, they can exhibit the same rigidity. As a result, it is possible to solve the problem of increased construction cost due to the recent rise in raw material prices of metal materials.

That is, the seismic piles composed of steel pipes having diameters of Φ 406 and Φ 812 may exhibit stiffness equal to or greater than that of general PHC piles having diameters Φ 506 and Φ 1500.

The guide rail 160 described above is configured to be inserted while the earth plate 200 is slid, and the earth plate 200 is easily slid and 'b' shaped or 'c' to prevent it from being pushed forward by the pressure of the earth and sand. 'Is formed of a sliding piece of shape. Guide rail 160 in the structure as described above in the entire length of the steel pipe pile 100, except that the steel pipe pile is embedded into the ground (10), that is, both sides of the steel pipe pile 100 at the portion where the trench is performed. It is formed symmetrically.

As shown in FIG. 2, the steel pipe pile 100 according to the embodiment of the present invention as described above, the upper pile (B) and the earth pile is installed in accordance with the excavation work is buried and fixed in the ground pile (B) ). That is, the lower pile (A) is provided with a rib 120, the expansion plate 130 at the front end is fixed by the concrete layer 3 deep in the underground (10), the steel pipe pile 100 can be more firmly supported In addition, the upper pile (B) is the earth plate 200 is inserted along the guide ray 160 to prevent the earth wall from collapsing.

On the other hand, although not shown, to the inside of the front end of the steel pipe 110 may be further coupled to the reinforcing bar member on the mesh in order to increase the coupling force of the concrete (3) and the steel pipe (110).

As shown in FIG. 4, the inside and the outside of the steel pipe pile introduced into the ground are filled with concrete 3, and the concrete 3 is mixed with a rust preventing admixture for preventing corrosion of the steel pipe.

The concrete poured on the steel pipe pile according to the prior art is generated by the separation of concrete and steel pipe at the stress concentration portion of the tip, but only depends on the rigidity of the steel pipe pile, in the embodiment of the present invention concrete coupled to the tip of the steel pipe (3) Since there is no material separation, the stiffness of the concrete is converted into steel pipe piles, which contributes to raising the rigidity of the steel pipe piles. In addition, the concrete filled in and out of the steel pipe increases the period of eigenvalues and the seismic load capacity is greatly improved.

5 is a process chart showing a process for constructing a steel pipe pile according to an embodiment of the present invention, Figure 6 is a perspective view showing the construction structure of the earthenware according to an embodiment of the present invention, Figure 7 is the earthenware according to an embodiment of the present invention Front sectional drawing which shows the construction structure.

The seismic resistant steel pipe pile 100 having the structure as described above is constructed by an embedding method. Referring to FIG. 5, the construction process is used to excavate the ground using the auger 1 to form an excavation hole 2 (a). (b). At this time, the case 4 is inserted at the same time as the excavation to maintain the excavation hole (2).

Subsequently, after injecting the steel pipe pile 100 according to the embodiment of the present invention into the excavation hole 2 (c), the concrete 3 is poured so that the steel pipe pile 100 in the ground is embedded in the concrete 3. After that, the case 4 is taken out (d).

The concrete 3 may be poured concrete by the concrete concrete both inside the steel pipe and between the steel pipe and the excavation walls, but if the gap between the steel pipe and the excavation walls is narrow, it may be filled with cement mortar between the steel pipe and the excavation walls. have.

At this time, the ribs 120 and the expansion plate 130 fixed to the front end of the steel pipe 110 is completely embedded in the concrete (3), the inside and outside of the steel pipe is filled with concrete, the rigidity of the concrete is converted into steel pipe pile Due to the increased rigidity, the steel pipe piles having diameters of φ406 and Φ812 according to the embodiment of the present invention exhibit the same cross-sectional force as the steel pipe piles having diameters of 506 and Φ1500 according to the prior art, respectively.

In addition, the outer diameter of the expansion plate 130 fixed to the bottom end of the steel pipe 110 is formed with a smaller difference than the diameter of the excavation hole (2), by being completely embedded in the concrete, the steel pipe 110 by a horizontal load The front end of the flow is prevented to ensure the seismic resistance.

The steel pipe pile 100 is purchased at a predetermined interval along the edge of the predetermined area to proceed with the excavation work, and after the predetermined time elapses after the concrete is sufficiently cured, the excavation is performed. Simultaneous sliding of the earth plate 200 along the guide rails 160 of the steel pipe pile 100 is performed at the same time as the digging process, thereby preventing the soil wall of the incision surface from falling down.

As shown in FIGS. 6 and 7, the excavation work up to a predetermined depth may be performed as described above. In addition, the top of the plurality of steel pipe pile 100 may be configured to be connected to each other by the connecting member 300 using H-shaped steel, etc. in order to improve the bearing capacity for the pressure of the earth and sand.

By using the seismic steel pipe pile 100 according to an embodiment of the present invention, the steel pipe pile 100 is buried in the ground stably supported, so that no additional side brace reinforcement is constructed, the construction can be carried out stably and efficiently Can be.

Although the embodiments of the present invention have been described with reference to the present invention, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom.

1 is a view showing a construction structure according to the prior art,

2 is a perspective view showing a steel pipe pile according to an embodiment of the present invention,

3 is a partial cross-sectional view showing a steel pipe pile according to an embodiment of the present invention,

4 is a partial cross-sectional view showing the underground penetration state of the steel pipe pile according to an embodiment of the present invention,

5 is a process chart showing a process for constructing a steel pipe pile according to an embodiment of the present invention;

6 is a perspective view showing the construction structure of the earthenware according to an embodiment of the present invention,

Figure 7 is a front sectional view showing a construction structure earth retaining according to an embodiment of the present invention.

** Description of symbols for the main parts of the drawing **

100: steel pipe pile 110: steel pipe

120: rib 130: expansion

160: guide rail

200: earth plate

300: connecting member

Claims (2)

Hollow cylindrical steel pipes; At least two ribs fixed radially outside the tip of the steel pipe; A donut-shaped expansion plate fixed to a bottom end of the steel pipe and a bottom of the rib; And Including the 'b' shape or 'c' shape guide rails symmetrically fixed to the outside of the steel pipe; including, The bottom buried portion of the steel pipe is fixed to the rib, the expansion plate is fixed by a concrete layer in the ground, the guide rail is sequentially inserted into the sliding plate, the top of the plurality of steel pipe is configured to be connected to each other by a connecting member Characteristic steel pipe piles. Digging the ground using an auger inserted into the case at regular intervals along the edge of the trench region to form a plurality of excavation holes; Ribs are radially fixed to the outside of the hollow cylindrical steel pipe tip portion inside the excavation hole, a donut-shaped bearing expansion plate is fixed to the bottom of the rib, 'b' shape or 'c' shape on the outside of the upper end of the steel pipe Inserting a steel pipe pile having a guide rail symmetrically fixed thereto; Placing concrete on an inner lower portion of the excavation hole to form a concrete layer; Removing the case while extracting the upper portion, and curing the concrete layer; Inserting the earth plate into the guide rail of the steel pipe pile as the trench proceeds; And Insulating retaining wall construction method comprising a; connecting each of the plurality of steel pipe pile top using a connecting member.

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