KR20210012525A - Steel structures and top-down method using it - Google Patents

Abstract

The present invention relates to a steel structure for coupling a pile and a top-down construction method using the same, wherein the steel structure for coupling a pile is installed on an upper surface of a PHC pile inserted into a support layer to function as an underground column of a building in the top-down construction method. The steel structure for coupling a pile includes: a beam embedded in the ground at an upper side of the support layer; a support plate fixed to a lower end of the beam to be mounted on an upper end of the PHC pile; and an insertion steel pipe fixed to the bottom of the support plate to be inserted into a central hole of the PHC pile, thereby easily connecting the beam functioning as the underground column to the PHC pile so that constructability can be improved.

Description

Steel structures and top-down method using it}

The present invention relates to a pile-coupled steel structure and a top-down method using the same, and in particular, to a pile-coupled steel structure capable of easily connecting a beam serving as a pillar of a building to a previously constructed PHC pile, and a top-down method using the same. will be.

In general, as a method of constructing the basement structure of a building, several construction methods have been developed from the prior art, and there may be several methods of classifying them, but if these are classified according to the direction of constructing and constructing the underground structure, it is largely pure. It can be roughly divided into a construction method and a reverse stroke method.

Among them, the back hitting method is also called the top-down method, which is a method devised as a method to simultaneously complete the ground floor and the basement layer as the ground height of the building increases and the required underground structure deepens. After constructing the basement outer wall and the basement pillar, it is possible to expect stability during underground construction and shortening of the total air by constructing an underground structure such as a floor slab in parallel with the excavation for each floor.

In this conventional top-down construction method, when constructing an underground pillar, a steel reinforcing bar is inserted into the perforated hole of the support layer, and then ready-mixed concrete is placed to create a PHC pile, and a steel structure such as a beam is inserted on the PHC pile, and then the ready-mixed concrete is poured again. Thus, the PHC pile and the beam are integrated.

Such a conventional method has a problem in that it is not easy to connect the previously constructed PHC pile and the steel structure.

Registered Patent 10-0788623

The present invention was devised to solve the problems of the prior art, and a pile-coupled steel structure capable of improving workability by easily and firmly connecting a beam serving as a pillar of a building and a PHC pile, and a top-down method using the same Its purpose is to provide.

The pile-coupled steel structure according to the present invention for solving the above problems is installed on the upper surface of the PHC pile inserted in the support layer to serve as a pillar of the building in the top-down construction method; A beam buried in the ground above the support layer; A support plate fixed to the lower end of the beam and seated at the upper end of the PHC pile; It consists of an insertion steel pipe fixed to the bottom of the support plate and inserted into the central hole of the PHC pile.

Here, the diameter of the inserted steel pipe becomes smaller as the lower portion goes toward the lower end.

In addition, a reinforcing bracket connecting the beam and the support plate is further installed.

In addition, an inlet hole through which cement milk or ready-mixed concrete is introduced is formed in the support plate, and an air outlet is provided next to the inlet hole.

On the other hand, the top-down method using a pile-coupled steel structure according to the present invention includes the steps of inserting a casing into the perforated hole while perforating the ground; Drilling the supporting layer under the ground to a predetermined depth after inserting the casing; Injecting cement milk into the casing; Connecting the auxiliary pile to the top of the PHC pile and inserting it into the casing; Hitting the connected PHC file and the auxiliary file; Separating and lifting the auxiliary file from the PHC file; Inserting the pile-coupled steel structure of the present invention into a casing and connecting it to the PHC pile; Aligning the beams by rotating the beams of the pile-coupled steel structure; Pouring cement milk or ready-mixed concrete into the casing; Filling soil into the casing; Lifting the casing; And filling the soil into the perforated hole after lifting the casing.

Here, after connecting the pile-bonded steel structure and the PHC pile, when cement milk or ready-mixed concrete is poured, it is poured to the top of the support plate of the steel structure.

The pile-coupled steel structure of the present invention constructed as described above and the top-down method using the same are applied to the PHC pile inserted under the support layer through the support plate fixed to the beam and the inserted steel pipe inserted into the PHC pile. Since the beam can be easily connected, there is an advantage of good workability.

1 and 2 are views showing the steel structure combined with the pile according to the present invention.
Figure 3 is a block diagram showing a simple top-down method using a pile-coupled steel structure according to the present invention.
4 to 16 are views sequentially showing the top-down method described in FIG. 3.

Hereinafter, with reference to the accompanying drawings, an embodiment of the steel structure combined with a pile according to the present invention will be described in detail.

1 and 2 are views showing a pile-coupled steel structure according to the present invention.

The pile-coupled steel structure according to the present invention is installed on the upper surface of the PHC pile (P) inserted in the support layer (E2) under the ground to serve as a pillar of the building in the top-down method, and the beam (10) and the It is configured to include a support plate 20 fixed to the lower end of the beam 10, and an insertion steel pipe 30 fixed to the bottom surface of the support plate 20.

The beam 10 is vertically buried in the ground above the support layer E2, and the upper portion protrudes above the ground E1 to become a solid pillar of the building. The beam 10 may have various shapes such as an H beam, a square beam, and a circular beam.

The support plate 20 is fixed to the lower end of the beam 10 by a method such as welding, and is mounted on the upper end of the PHC pile P.

Incidentally, in the PHC pile P, a plate P1 through which a central portion is passed is bolted to the upper end, and as is well known, a central hole P2 is formed in the center in the vertical direction. The support plate 20 is mounted on the upper surface of the plate P1 of the PHC pile P, and is installed to be located inside the ring P3 formed on the upper surface of the plate P1.

The support plate 20 installed in this way not only prevents the beam 10 from shaking left and right, but also prevents the beam 10 from falling into the central hole P2 of the PHC pile P.

On the other hand, between the beam 10 and the support plate 20, a reinforcing bracket 40 connecting the two is installed by welding or the like to hold the beam 10 firmly and distribute the load.

In addition, an inlet hole 21 is formed in the support plate 20 and an air outlet 22 is provided.

The inlet hole 21 is a hole through which cement milk or ready-mixed concrete is introduced, and the PHC pile (P) and the steel structure of the present invention are rigidly integrated by the cement milk or ready-mixed concrete introduced through this place.

The air outlet 22 is provided next to the inlet hole 21 and protrudes to a predetermined height on the upper surface of the support plate 20. When cement milk or ready-mixed concrete is introduced through the inlet hole 21, air is discharged to the outside through the air outlet 22.

The inserted steel pipe 30 is fixed to the bottom of the support plate 20 by welding or the like, and when the support plate 20 is seated on the upper surface of the plate P1 of the PHC pile P, the central hole of the PHC pile P It is inserted in (P2).

The inserted steel pipe 30 has an outer diameter equal to or substantially similar to the diameter of the central hole P2 of the PHC pile P to prevent the beam 10 from shaking.

In addition, the insertion steel pipe 30 is formed to have a smaller diameter as the lower portion goes toward the lower end. Therefore, the insertion steel pipe 30 can be easily inserted into the central hole P2 of the PHC pile P.

Hereinafter, an embodiment of a top-down method using a pile-coupled steel structure according to the present invention will be described.

3 is a schematic block diagram showing a top-down method using a pile-coupled steel structure according to the present invention, and FIGS. 4 to 16 are views sequentially showing the top-down method described in FIG. 3.

The top-down construction method using the pile-coupled steel structure according to the present invention configured as described above is completed through a process of several steps.

The first step (S1) is a process of inserting the casing (C) into the hole formed at this time while drilling the ground using an auger after performing the soil barrier construction and order grouting by the CIP (Cast in place pile) method. Since the casing (C) is directly inserted while drilling the ground, it is possible to prevent the soil from collapsing and the drilling hole from being buried.

In the second step (S2), after the casing (C) insertion is completed in the first step (S1), a certain depth is drilled under the support layer (E2) that is harder than the ground while being under the ground. At this time, the casing (C) is not inserted into the support layer (E2), but is inserted only in the ground above the support layer (E2).

To explain more here, in the top-down method, the underground space from the support layer (E2) to the ground (E1) is excavated to a certain depth in sequence, and then the space that forms the basement layer of the building goes through the process of constructing the floor slab. do.

The third step (S3) is a process of injecting cement milk into the casing (C). At this time, the injected cement milk is filled to a certain height in the hole formed in the support layer E2.

The fourth step (S4) is a process of connecting the auxiliary pile 50 to the top of the PHC pile (P) and inserting it into the casing (C). When connecting the PHC file (P) and the auxiliary file (50), use the auxiliary file connection and disassembly device suggested in Application No. 10-2017-0174029 (Name of the invention: auxiliary file connection and disassembly device and file construction method using the same). If you use it, you can perform the connection work more conveniently.

The fifth step (S5) is a process of hitting the connected PHC file (P) and the auxiliary file (50) with a hammer (H).

In the sixth step (S6), after separating the auxiliary file 50 from the PHC file P, the PHC file P is left as it is and only the auxiliary file 50 is lifted. As described above, when connecting the PHC file (P) and the auxiliary file (50), the auxiliary file connection suggested in Application No. 10-2017-0174029 (Name of the invention: auxiliary file connection and dismantling device and file construction method using the same) And when the disassembly device is used, the plate P1 remains at the top of the PHC pile P when the auxiliary pile 50 is separated from the PHC pile P.

The seventh step (S7) is a process of inserting the pile-coupled steel structure 100 according to the present invention described above into the casing (C) and connecting it to the PHC pile (P).

When the pile-coupled steel structure 100 of the present invention is inserted into the casing (C), the support plate 20 is in close contact with the upper surface of the plate (P1) of the PHC pile (P), and the inserted steel pipe (30) is the center of the PHC pile (P). It is inserted into the hole P2.

The eighth step (S8) is a process of aligning the beam 10 by rotating the beam 10 of the pile-coupled steel structure 100.

The beam 10, which serves as an underground pillar of a building, is designed to face a certain direction, but there are cases where the direction of the beam 10 is not as designed during construction. In this case, the beam 10 is rotated clockwise or counterclockwise around the longitudinal direction of the beam 10 to align the left and right as designed.

The ninth step (S9) is a process of pouring cement milk or ready-mixed concrete into the casing (C). When pouring cement milk or ready-mixed concrete in this way, it is preferable to pour it up to the top of the support plate 20 of the steel structure 100. Only then can the steel structure 100 and the PHC pile (P) increase the bonding force to be solidly integrated.

And, when the cement milk or ready-mixed concrete is poured in this way, the cement milk or ready-mixed concrete is introduced into the insertion steel pipe 30 and the PHC pile P through the inlet hole 21 of the support plate 20.

The tenth step (S10) is a process of filling soil in the casing (C). In the seventh step (S9), the space not filled by cement milk is filled with soil.

The eleventh step (S11) is a process of lifting the casing (C) inserted into the perforated hole.

The twelfth step (S12) is a process of lifting the casing (C) and filling the soil in the hole.

Through this process, after the pile-coupled steel structure 100 and the PHC pile (P) of the present invention are integrated and stably positioned in the perforated hole, the next step (S13) goes from the top to the bottom to the planned excavation depth. After excavation, the first basement floor slab is constructed, and the second basement floor slab is constructed by continuing to excavate again to the planned excavation depth, and the basement layer of the building is constructed by repeating the excavation and construction process of the floor slab.

10: beam 20: support plate
21: inlet hole 22: air outlet
30: insert steel pipe 40: reinforcement bracket
100: pile-coupled steel structure 50: auxiliary pile
C: Casing P: PHC pile
P1: Plate P2: Central hole
P: ring

Claims (6)

It is installed on the upper surface of the PHC pile (P) inserted in the support layer (E2), and plays the role of a pillar of the building in the top-down method,
A beam 10 buried in the ground above the support layer E2;
A support plate 20 fixed to the lower end of the beam 10 and seated at the upper end of the PHC pile P;
An insert steel pipe 30 fixed to the bottom of the support plate 20 and inserted into the central hole P2 of the PHC pile P.
The method according to claim 1,
The inserted steel pipe 30 is a pile-coupled steel structure, characterized in that the diameter decreases toward the lower side of the lower side.
The method according to claim 1,
A pile-coupled steel structure, characterized in that a reinforcing bracket (40) connecting the beam (10) and the support plate (20) is further installed.
The method according to claim 1,
The support plate 20 is formed with an inlet hole 21 through which cement milk or ready-mixed concrete is introduced, and an air outlet 22 is provided next to the inlet hole 21.
Inserting the casing (C) into the drilling hole while drilling the ground (S1);
Drilling the supporting layer (E2) under the ground to a predetermined depth after insertion of the casing (C) (S2);
Injecting cement milk into the casing (C) (S3);
Connecting the auxiliary file 50 to the upper end of the PHC file P and inserting it into the casing C (S4);
A step (S5) of hitting the connected PHC file (P) and the auxiliary file (50);
Separating and lifting the auxiliary file 50 from the PHC file P (S6);
Inserting any one of the pile-coupled steel structure 100 of claims 1 to 4 into the casing (C) and connecting it to the PHC pile (P) (S7);
Aligning the beam 10 by rotating the beam 10 of the pile-coupled steel structure 100 (S8);
Pouring cement milk or ready-mixed concrete into the casing (C) (S9);
A step (S10) of filling soil into the casing (C);
Lifting the casing (C) (S11);
Top-down construction method using a pile-coupled steel structure comprising a; step (S12) of filling the soil into the perforated hole after lifting the casing (C).
The method of claim 5,
After connecting the pile-bonded steel structure 100 and the PHC pile (P), when pouring cement milk or ready-mixed concrete, a pile-coupled steel structure, characterized in that pouring to the top of the support plate 20 of the steel structure 100 Top-down method used.

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