KR101383817B1 - Top down method - Google Patents

Abstract

Inverted construction method according to the present invention, the simultaneous construction of the underground structure and the ground structure is possible, because the use of PC pillars do not require a separate column reinforcement work has the effect that the construction period and cost can be reduced. In addition, by using a PC pillar formed by pouring refractory concrete incorporating organic fibers, high strength can be obtained compared to the cross section, and the cross section of the PC pillar can be reduced to reduce weight. In addition, since at least a part of the PC pillar is made of a hollow shape, there is an effect that can reduce the weight of the PC pillar, and can be applied because the concrete can be selectively placed in the hollow to suit the strength of the PC pillar required in the field This is an easy advantage. In addition, a shear key is provided on a lower circumferential surface fixed to the pile in the PC pillar, and at least a portion of the bottom surface of the PC pillar is formed to be inclined downward, thereby strengthening the coupling between the PC pillar and the pile, and the contact surface of the PC pillar and the pile. There is an effect that the pile can better support the weight transmitted by the PC pillar by increasing the. In addition, by forming a basement pillar by joining the steel frame in the longitudinal direction on the top of the PC pillar, it is possible to reduce the weight of the basement pillar can reduce the burden of the crane used to lift the basement pillar.

Description

Reverse down method {Top down method}

The present invention relates to a reverse drilling method and a building structure to which the same is applied, and more particularly, after inserting a PC column into the ground and performing excavation step by step in the ground, the ground construction is performed together with the underground construction. It relates to a reverse punching method that can be carried out and a building structure applying the same.

In general, the top down method is a construction method for constructing the basement floor while gradually descending from the ground slab to the ground level gradually.

In the conventional reverse drilling method, steel structures are used as underground columns and inserted into the ground, and underground structures such as beams and floor slabs are constructed in the excavation space while excavating the surrounding ground of the steel structures. Thereafter, reinforcing bars are disposed as if the steel frame is surrounded, and concrete is poured to build steel reinforced concrete columns.

Korean Patent Laid-Open Publication No. 015034 discloses a technique for simultaneously constructing a basement and a ground floor frame at the same time when constructing a high-rise building, and discloses a reverse perforation method of a building structure having a steel reinforced concrete structure.

As described above, when the steel frame is inserted into the base column, there is a limit to supporting the weight of the ground, it is necessary to reinforce the column surrounding the steel frame with steel and concrete. In addition, since the construction of the ground after the pillar reinforcement work has a problem that the construction period is long. In addition, when the ground work is to be started before the pillar reinforcement work, there is a problem in that the cost is increased because the cross section of the steel frame must be increased to secure the bearing capacity of the steel frame. In addition, the construction period is long because the work required to wrap around the steel frame with steel and concrete during the underground construction.

An object of the present invention is to provide a reverse construction method that can shorten the construction period and reduce the construction cost and building structures to which the same.

The reverse drilling method according to the present invention comprises the steps of excavating a pillar insertion hole in the ground, and suspending one or a plurality of PC pillars coupled in series and inserting the pillar insertion hole into the lower portion of the inside of the pillar insertion hole. Forming a pile and fixing the PC pillar; and constructing a ground floor on the upper portion of the PC pillar; It includes the step-by-step construction.

Reverse drilling method according to another aspect of the present invention, the step of excavating the pillar insertion hole in the ground, the step of joining the steel frame on the upper portion of the PC pillar in the longitudinal direction, and hanging the PC pillar is joined to the steel frame to insert the pillar Inserting into the hole, placing concrete under the inside of the pillar insertion hole to form a pile and fixing the PC pillar, and constructing a ground floor on the upper end of the steel frame, and then Stepwise excavation of the ground includes the step of constructing the structure of each underground floor.

In the reverse drilling method according to the present invention, by inserting and fixing a PC pillar in the pillar insertion hole formed in the excavation in the ground, by stepping on each of the underground structure and ground structure supported by the PC pillar, simultaneous construction of the underground structure and the ground structure Construction is possible, and because the use of PC pillars do not require a separate column reinforcement work, there is an effect that can reduce the construction period and cost.

In addition, by using a PC pillar formed by pouring refractory concrete incorporating organic fibers, a high strength relative to the cross section can be obtained, so that the cross section can be further reduced to reduce the weight of the PC pillar. It is possible to reduce the burden on the crane to lift the PC pillar.

In addition, since at least a part of the PC pillar is made of a hollow shape, there is an effect that can reduce the weight of the PC pillar, and can be applied because the concrete can be selectively placed in the hollow to suit the strength of the PC pillar required in the field This is an easy advantage.

In addition, by forming a shear key on the lower outer peripheral surface of the PC pillar, and by embedding the lower portion of the PC pillar, the PC pillar and the pile can be firmly coupled. In addition, by embedding the PC pillar in a pile having a larger cross-sectional area than the PC pillar, the load of the PC pillar is diffused to the pile has an effect that the pile can better support the load of the PC pillar. In addition, at least a portion of the lower surface of the PC pillar is formed to be inclined downward to prevent the occurrence of voids between the lower surface of the PC pillar and the pile when the lower portion of the PC pillar is embedded into the pile, the PC pillar and the The contact surface of the pile is increased to have an effect that the pile can better support the load of the PC column.

In addition, by forming a basement pillar by joining the steel frame in the longitudinal direction on the top of the PC pillar, it is possible to reduce the weight of the basement pillar can reduce the burden of the crane used to lift the basement pillar.

1 is a flowchart showing a reverse drilling method using a PC column according to a first embodiment of the present invention.
FIG. 2 is a view illustrating the PC pillar illustrated in FIG. 1.
3 is a sectional view taken along the line AA in Fig.
4 is a sectional view taken along line BB of Fig.
FIG. 5 is a view illustrating a state in which a beam or slab is coupled to the PC pillar illustrated in FIG. 1.
6 is a view showing a PC pillar according to a second embodiment of the present invention.
7 is a view showing a coupling state of the PC pillar and the pile according to the second embodiment of the present invention.
8 is a view showing a base column joined to the steel frame and the PC pillar according to a third embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a flowchart showing a reverse drilling method using a PC column according to a first embodiment of the present invention. 2 is a view showing a state in which the PC pillar shown in Figure 1 is fixed to the pile. 3 is a sectional view taken along the line A-A in Fig. 4 is a sectional view taken along the line B-B in Fig. FIG. 5 is a view illustrating a state in which a beam or slab is coupled to the PC pillar illustrated in FIG. 1.

In the reverse drilling method, as shown in FIG. 1A, an earth wall 10 is constructed at a boundary of a place where a building structure is to be installed. The retaining wall 10 is also referred to as a slurry wall, and excavates the ground 1 to build concrete walls by pouring concrete while preventing the collapse of the ground using a stabilizer.

Thereafter, as shown in FIG. 1B, the pillar insertion hole 20 is vertically excavated in the ground 1.

The position and the number of the pillar insertion holes 20 are set according to the position and the number of the PC pillars 30 to be described later, and the position and the number of the PC pillars 30 are determined according to the structure of the building structure. In addition, the depth of each of the pillar insertion holes 20 is determined according to the length of the PC pillar 30 and the length of the pile 40.

The PC (Precast Concrete) column 30 is a reinforced concrete column manufactured in advance at a construction site or a factory in the construction site. The PC pillar 30 may be manufactured in a factory so that one is made in a predetermined length, and in the factory, a plurality of pieces having a length shorter than the predetermined length may be manufactured, and the plurality of PC pillars may be combined and combined at a construction site. It is also possible for the total length of the PC pillars to be the predetermined length. In the case of manufacturing at a length shorter than the predetermined length in the factory, transportation becomes easy. In the present embodiment will be described as an example to use as a PC pillar 30 coupled to the plurality of PC pillars to a predetermined length in the construction site.

The PC column 30 is inserted into the pillar insertion hole 20 by using the equipment (2).

The weight of the PC pillar 30 needs to be set in a range within which the equipment 2 can be lifted. This will be described later in detail.

There are two methods for the construction procedure for embedding and fixing the lower part of the PC pillar 30 inside the concrete of the pile 40.

In the first method, the lower end of the PC pillar 30 is positioned by using the equipment 2 at a predetermined position determined according to the building structure, and concrete is poured into the lower portion of the pillar insertion hole 20 to allow the PC pillar ( The lower part of the 30 is embedded in the concrete of the pile 40 to be fixed.

In the second method, the PC pillar 30 is suspended by using the equipment 2 to be positioned above the concrete upper end of the pile 40, and after the concrete of the pile 40 is poured, the PC is placed. The pillar 30 is lowered to the predetermined position, and the PC pillar 30 is embedded in the pile. The upper end of the PC pillar 30 is also possible to fix the position using a holder (not shown) in addition to the equipment (2). In the present embodiment, after pouring the PC pillar 30 in the state in which the equipment 2 is suspended, the concrete is poured into the inner lower portion of the pillar insertion hole 20, and then the PC pillar 30 is placed at the predetermined position. For example, the latter method of lowering is used. When the lower portion of the PC pillar 30 is inserted into the concrete of the pile 40 and embedded, the PC pillar 30 is fixed to the pile 40 by curing the concrete.

Referring to FIG. 1C, when curing of the pile 40 is completed and fixing of the PC pillar 30 is completed, the ground floor is constructed. On the upper side of the PC pillar 30 is installed the ground first floor slab 50 to form a ground first floor. After installing the ground ground slab 50, the ground of the lower ground slab 50 is excavated step by step to perform the underground construction. When the ground is excavated, the upper portion of the PC pillar 30 is exposed, and an underground beam or an underground slab 70 of the corresponding floor is installed on the exposed ground portion. After installing the basement slab 70, and then excavating the ground of the lower layer, and the ground is excavated to install an underground slab of the lower layer in the exposed portion of the PC pillar (30). By repeating the above process, the contractor constructs the structures of each floor underground.

Referring to FIG. 1D, the construction 60 of each ground layer is also constructed step by step while constructing the structures of each underground layer. The ground pillar 61 is installed on the upper part of the PC pillar 30, and the ground beam or ground slab 62 is installed step by step at a height corresponding to each layer of the ground pillar 61. Therefore, the ground work and the underground work can be done together, the construction period can be shortened.

2 and 4, the PC pillar 30 according to the present embodiment is at least partially hollow in order to reduce the weight. That is, the PC pillar 30 is composed of a solid portion 32 filled with concrete and the hollow portion 31 which is extended to the upper portion of the solid portion 32 so that concrete is not poured therein. The hollow part 31 may be filled with concrete at the site, or may be used while the hollow part is not filled with concrete.

In this embodiment, the PC pillar 30 is fixed to the pile 40, and then, for example, the concrete is poured into the hole 31a of the hollow part 31 to be described.

When the required strength of the PC pillar 30 exceeds the design strength, the concrete is poured into the hole 31a of the hollow part 31 so that the strength of the PC pillar 30 on which the concrete is poured exceeds the required strength. Let's do it.

The required strength is determined according to the characteristics of the ground, the height or structure of the underground and ground structures. On the other hand, when the required strength of the PC pillar 30 is satisfied with the design strength, it is also possible to use the concrete without placing concrete in the hole (31a) of the hollow portion 31. In addition, in the present embodiment, for example, at least a part of the PC pillar 30 is formed in a hollow shape, for example, but is not limited to this, of course, all the parts of the PC pillar 30 is made of a hollow shape, of course. It is possible. In addition, in the present embodiment, as illustrated in FIGS. 3 and 4, the cross-sections of the hollow portion 31 and the faithful portion 32 of the PC pillar 30 will be described as an example, for example. The present invention is not limited to this, but may be made of a cross section of other shape such as a circular cross section or a polygon. In addition, each corner of the PC pillar 30 is formed to have a polygonal cross-section of the chamfered shape, it is of course possible to reduce the weight while having sufficient strength.

In addition, the PC pillar 30 is important to have a high strength to reduce the weight, but can sufficiently support the load. Therefore, in the present embodiment, the PC pillar 30 uses the high-strength refractory concrete incorporating organic fibers in order to prevent explosion in the event of fire. When the high strength refractory concrete is used, the cross section of the PC pillar 30 can be reduced so that the weight can be reduced.

In addition, referring to FIG. 5, the PC pillar 30 has a fitting hole 30a into which the reinforcing bar 71 provided in the basement beam or the basement slab 70 is fitted. The reinforcing bar 71 is inserted into the fitting hole 30a, and then fixed using mortar or the like. Meanwhile, the present invention is not limited thereto, and a fitting member (not shown) made of reinforcing bars or metal materials may be installed in the fitting hole 30a to be combined with the reinforcing bars 71 of the underground slab 70.

6 and 7 illustrate a PC pillar according to a second embodiment of the present invention.

6 and 7, the PC pillar 100 according to the second embodiment of the present invention includes a shear key 102 fixed to the pile 110 on a lower circumferential surface thereof, and the PC pillar 100. ) Is different from the first embodiment in that the lower surface is formed in a convex shape toward the center, and will be described in detail with respect to different points. As shown in FIG. 6, the lower surface 104 of the PC pillar 100 may have a conical shape that is inclined downward toward the center portion. The inclination angle of the lower surface 104 may be determined by other design requirements such as the cross-sectional area of the PC pillar 100 or the cross-sectional area of the pile 100. In addition, as shown in FIG. 7, the bottom surface 134 of the PC pillar 100 includes at least a portion of the inclined portion 134a formed to be inclined downward, and the rest of the PC pillar 100 has a flat surface portion 134b. It is possible.

After inserting the PC pillar 100 into the pillar insertion hole 20, concrete is poured into the pillar insertion hole 20 using a trem tube to form the pile 110. When the concrete is poured, the concrete is filled from the inner lower portion of the pillar insertion hole 20, and the lower end of the PC pillar 100 is embedded in the concrete. At this time, the lower portion of the PC pillar 100 is formed to protrude convexly downward toward the center portion, the concrete is gradually filled in the circumferential direction from the center of the lower surface of the PC pillar 100 when the concrete is placed. . Therefore, it is possible to prevent the generation of voids on the lower surface of the PC pillar 100.

In addition, the shear key 102 is a groove formed on the outer circumferential surface of the PC pillar 100. The shear key 102 is formed in plural on the outer peripheral surface of the PC pillar (100). Since concrete enters the shear key 102 when the concrete is placed for the pile 110, the PC pillar 100 and the pile 110 may be more firmly coupled.

The weight of the PC pillar is axially transmitted to the pile 110 through the contact surface between the PC pillar 100 and the pile 110. Since the lateral cross-sectional area of the pile 110 is greater than the lateral cross-sectional area of the PC pillar 100, the pile 110 can effectively support the load transmitted from the PC pillar 100. In addition, the load transmitted from the PC pillar 100 may be transmitted to the pile 110 by the shear key 102.

In Figure 6, the underground excavation is carried out is shown a state in which the mat foundation 120 is installed on the top of the pile 110. The PC pillar 100 is provided with a fitting hole so that the reinforcing bar 121 provided in the mat base 120 is fitted.

After the reinforcing bars 121 are inserted into the fitting holes, the mortar is filled and fixed. However, the present invention is not limited thereto, and the PC pillar 100 may be provided with a reinforcing bar or a coupling part made of a separate metal, and may be combined with the reinforcing bar 121.

8 is a diagram illustrating an underground column 300 to which a steel frame and a PC column are joined according to a third embodiment of the present invention.

Referring to FIG. 8, the basement pillar 300 is different from the first and second embodiments in which the steel frame 310 is joined in the longitudinal direction to the upper portion of the PC pillar 320. do.

The basement pillar 300, the lower portion that the large load acts during the construction is made of PC pillar 320, can bear both the load during the underground construction and ground construction. Since the load acting on the upper part of the underground column 300 is relatively small since it is the initial load that started the ground work, the upper part of the underground column 300 is made of the steel frame 310.

The PC pillar 320 may be formed in a hollow shape in which concrete is not filled therein, or may be formed in a shape in which concrete is filled therein.

The range and size of the steel frame 310 used for the underground column 300 may be set differently according to the process ratio of the underground construction and the ground construction, thereby optimizing the construction period and cost. Since the underground pillar 300 to which the steel frame 310 and the PC pillar 320 are bonded may be effectively reduced in weight than when the entire pillar is made of a PC pillar, the burden of the crane lifting the underground pillar 300 is increased. Can be reduced. In addition, the steel frame 310 may be a pillar of the steel frame reinforced concrete structure by wrapping the reinforced concrete during underground construction as needed.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

1: ground 10: retaining wall
20: pillar insertion hole 30, 100: PC pillar
31: hollow part 32: faithful part
40: pile 102: shear key
300: underground pillar 310: steel frame
320: PC pillar 330: stake

Claims (12)

Digging a pillar insertion hole in the ground;
A plurality of PC pillars, which are connected in series or in series and formed with a plurality of grooves forming a shear key on a lower circumferential surface thereof, are suspended by using a holder or a device so that the lower end of the PC pillar is positioned above the upper end of the pile. Inserting;
After the concrete is formed by pouring concrete into the inner lower portion of the pillar insertion hole, the PC pillar is lowered downward to form a flat portion formed flat in the center of the lower surface of the PC pillar and an inclined portion formed to be inclined upwardly around the plane portion. Embedding and fixing the pile;
Constructing the ground floor on the upper end of the PC column, and constructing the structures of each underground floor step by step while digging the ground of the lower ground floor;
And installing a mat base on the top of the pile, and inserting reinforcing bars provided on the mat base into the fitting holes formed in the PC pillar, and filling and fixing the mortar. Digging a pillar insertion hole in the ground;
Bonding the steel frame in the longitudinal direction to an upper portion of the PC pillar on which a plurality of grooves forming a shear key are formed on the lower circumferential surface;
Suspending the PC pillar to which the steel frame is joined using a holder or a device, and inserting the PC pillar into the pillar insertion hole so that the lower end of the PC pillar is positioned above the upper end of the pile;
After the concrete is formed by pouring concrete into the inner lower portion of the pillar insertion hole, the PC pillar is lowered downward to form a flat portion formed flat in the center of the lower surface of the PC pillar and an inclined portion formed to be inclined upwardly around the plane portion. Embedding and fixing the pile;
Constructing the ground floor on the upper end of the steel frame and constructing the structures of each underground layer step by step while digging the ground of the lower ground floor;
And installing a mat base on the top of the pile, and inserting reinforcing bars provided on the mat base into the fitting holes formed in the PC pillar, and filling and fixing the mortar. delete The method according to claim 1 or 2,
At least a portion of the PC pillar, the reverse drilling method is made by pouring refractory concrete. The method according to claim 1 or 2,
The PC pillar is a reverse drilling method consisting of a solid part fixed to the pile and filled with concrete as a whole, and a hollow part extending from an upper part of the faithful part and in which no concrete is poured. The method of claim 5,
When the required strength of the PC pillar exceeds the design strength, the reverse drilling method for placing the concrete in the hollow portion after fixing the PC pillar to the pile. The method according to claim 1 or 2,
The structure of each layer below the ground includes a bona slab,
The PC pillar is a reverse punching method provided with a metal coupling portion so that the beam or slab is coupled. delete delete delete delete delete

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