KR102249326B1 - Embedded pipes for columns - Google Patents

Abstract

In the present invention, by providing a mesh-shaped tremi tube composed of a mesh body with open top and bottom in the longitudinal direction of the column member in the column formwork, it is easy to install even in a narrow casting space, and does not hinder the integration of concrete inside the column member, It is about a buried-type pouring pipe for pillar pouring that can minimize material separation when pouring concrete, and in which concrete can be poured tightly around the pouring tremi pipe.
In the present invention, the buried-type pouring pipe for casting a column is provided in the longitudinal direction of the column member in the inner space of the column formwork for placing the column member concrete, and the upper part is fixed to the main stiffener provided inside the column form, and the lower part is fixed separately. It is a tubular shape composed of a mesh body that is opened up and down by rolling the mesh in a cylindrical shape, and the size of the mesh is formed to be less than the maximum size of the aggregate of the concrete to be poured, and a plurality of discharge holes are formed on the outer circumferential surface and injected through the top. A mesh-shaped tremi pipe in which most of the concrete is discharged downward through the inside of the mesh-shaped tremi pipe, while a part of the concrete containing paste flows downward through the mesh through the outer circumferential surface; And a guide sleeve having a lower portion inserted into the upper portion of the mesh-shaped tremi pipe so as to guide the concrete supplied from the outside into the inside of the mesh-shaped tremi pipe. It characterized in that it consists of.

Description

Embedded pipes for columns

In the present invention, by providing a mesh-shaped tremi tube composed of a mesh body with open top and bottom in the longitudinal direction of the column member in the column formwork, it is easy to install even in a narrow casting space, and does not hinder the integration of concrete inside the column member, It is about a buried-type pouring pipe for pillar placement that can minimize material separation during concrete pouring and that concrete can be poured tightly around the pouring tremi tube.

In the structure, the column member is a member that transmits vertical load and is characterized by being long and elongated vertically.

In general, reinforced concrete column members are constructed by installing a column form on the outside after assembling the reinforcing bar, and pouring concrete inside the column form from the top.

Since the height of such a column member is high, concrete material separation occurs when concrete is poured directly from the top of the formwork. Therefore, it is necessary to manage the free fall height of the concrete to be poured within 1.5m.

For this, conventionally, a corrugated pipe (flexible hose) was inserted into the column member to adjust the spacing between the pouring surface and the corrugated pipe, and concrete was poured while raising the corrugated pipe.

However, as shown in Fig. 1, when a cross-shaped H-beam (3) for beam connection is provided inside the PSRC member, which is a factory pre-assembled SRC joint, or in the case of a CFT column with an inner diaphragm, inserting a corrugated pipe into the column member is required. It is difficult to secure space for it.

And since it is difficult to maintain the linearity of such a corrugated pipe, it is difficult to insert the corrugated pipe to the lower part when the height of the column is high. In addition, when the corrugated pipe is raised, it is often difficult to ascend due to interference with the internal structure of the column member.

Accordingly, a technology for a "concrete pouring pipe embedded filling column" was developed in which a concrete pouring pipe with a plurality of concrete pouring holes perforated on the side is inserted into the steel column and concrete is poured through the concrete pouring hole. No. 10-2017-0132559).

However, since the above technology uses a pipe such as a spiral duct as a pipe for pouring concrete, it is difficult to adjust the diameter and thus, it is not easy to respond to various pouring spaces.

In addition, since the closed section pipe is used, the concrete inside and outside the pipe is separated to form an interface, thereby inhibiting the integral behavior, which is structurally disadvantageous.

Furthermore, when the pipe for concrete placement is fixed to the main stiffener or formwork of a column member such as cast steel or cast reinforcement, a narrow space is created between the pipe for pouring concrete and the main reinforcement or formwork.In these narrow gaps, concrete is not tightly filled. there is a problem.

In addition, since concrete is discharged only through the concrete pouring hole, the number of concrete pouring holes must be increased.In this case, the amount of concrete discharged from the pouring hole located far from the pouring surface may increase, and material separation may occur.

In order to solve the above problems, the present invention is to provide a buried-type pouring pipe for placing a column that is easy to install even in a narrow pouring space.

An object of the present invention is to provide a buried-type pouring pipe for pouring a pillar that does not hinder the integration of concrete inside the pillar member.

An object of the present invention is to provide a buried-type pouring pipe for placing a column in which material separation can be minimized when concrete is placed, and concrete can be placed tightly around a tremi pipe for pouring.

The present invention according to a preferred embodiment is provided in the longitudinal direction of the column member in the inner space of the column formwork for placing the column member concrete, and the upper part is fixed to the main reinforcement provided inside the column formwork, and the lower part is not separately fixed. It is a tubular shape composed of a mesh body with an open top and bottom by rolling the net in a cylindrical shape, and the size of the net is formed to be less than the maximum size of the aggregate of the concrete to be poured, and a plurality of discharge holes are formed on the outer circumferential surface of the concrete injected through the top. A mesh-shaped tremi pipe in which most of the material is discharged to the lower portion through the inside of the mesh-shaped tremi pipe, while a part of the concrete containing paste flows downward through the mesh through the outer circumferential surface; And a guide sleeve whose lower portion is inserted into the upper portion of the mesh-shaped tremi pipe to guide the concrete supplied from the outside into the inside of the mesh-shaped tremi pipe. It provides a buried-type pouring pipe for pouring pillars, characterized in that consisting of.

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According to the present invention, there are the following effects.

First, a mesh-shaped tremi tube composed of an open mesh body is provided in the column form in the longitudinal direction of the column member. Accordingly, most of the concrete injected through the top of the mesh tremi tube is discharged to the lower side through the inside of the mesh tremi tube, and a part of the concrete flows down the outer circumferential surface of the mesh tremi tube through the net, so that the concrete can be tightly filled.

Second, when the mesh-shaped tremi tube is formed of metal lath or wire mesh, the cross-sectional shape can be freely deformed, so that it can be easily installed in a space where the upper space of the column member is narrow.

Third, since concrete is filled between the mesh eyes of the mesh tremi pipe, the mesh tremi pipe itself is integrated with the concrete inside the column member. Therefore, it is possible to prevent the concrete from separating inside and outside the mesh-shaped tremi tube.

1 is a plan view showing a panel zone of a PSRC column.
Fig. 2 is a perspective view showing a mesh-shaped tremi tube constituting the present invention.
3 is a plan view showing an installation position of a mesh-shaped tremi tube.
4 is a side view showing a state in which a guide sleeve is installed in a mesh-shaped tremi tube.
Figure 5 is a side cross-sectional view showing a concrete pouring process.
Fig. 6 is a perspective view showing a fixed state of a mesh-shaped tremi tube by a fixing band.
7 is a photograph showing the actual construction state of the mesh-shaped tremi tube.
Figure 8 is a photograph showing the actual state of the concrete pouring by the present invention for pillar pouring type embedded pouring pipe.

Hereinafter, the present invention will be described in detail according to the accompanying drawings and preferred embodiments.

Fig. 2 is a perspective view showing a mesh-shaped tremi pipe constituting the present invention, and Fig. 3 is a plan view showing an installation position of the mesh-shaped tremi pipe.

As shown in Figures 2 and 3, the present invention is a buried-type pouring pipe for pillar pouring is provided in the inner space 10 of the pillar formwork 1 for the pillar member concrete pouring in the longitudinal direction of the pillar member, and the upper part is the above It is fixed to the main stiffener 2 provided inside the column formwork 1, and the lower part is not fixed separately.It is a tubular shape composed of a mesh body with open top and bottom by rolling the net into a cylindrical shape, and the size of the net is poured. It is formed to be less than the maximum size of the aggregate of concrete, and a plurality of discharge holes 41 are formed on the outer circumferential surface, so that most of the concrete injected through the upper part is discharged to the lower part through the inside of the mesh-shaped tremi pipe 4, while the paste is discharged. Some of the concrete included is a mesh-shaped tremi tube 4 that flows down the outer circumferential surface through the mesh eye; It characterized in that it is configured to include.

The present invention is easy to install even in a narrow pouring space, does not impede the integration of concrete inside the column member, minimizes material separation when pouring concrete, and allows concrete to be poured tightly around the tremi pipe for pouring. It is to provide a recessed-type pouring pipe for placing pillars.

In the present invention, the embedded-type pouring pipe for casting pillars is configured to include a mesh-shaped tremi pipe (4).

The mesh-shaped tremi tube 4 is provided in the longitudinal direction of the column member, and is composed of a mesh body with open top and bottom.

Conventionally, concrete was poured using a pipe of a closed cross section, but in the present invention, the pouring pipe was improved to a mesh-shaped tremi pipe 4 having a network structure, focusing on the fluidity and viscous properties of the concrete.

The mesh-shaped tremi pipe 4 can be configured by rolling a mesh such as metal lath or wire mesh in a cylindrical shape to form a tubular shape.

This mesh-shaped tremi tube 4 is lightweight and easy to handle.

The concrete injected through the upper portion of the mesh-shaped tremi pipe 4 is mostly discharged to the lower side through the inside of the mesh-shaped tremi pipe 4. In addition, some of the concrete, such as paste, flows down through the mesh of the mesh-shaped tremi pipe 4 along the outer circumferential surface of the mesh-shaped tremi pipe (4).

Accordingly, even if the surrounding space of the mesh-shaped tremi tube 4 is narrow, concrete can be tightly filled.

In addition, since concrete is also filled between the mesh eyes of the mesh-shaped tremi pipe 4, the mesh-shaped tremi pipe 4 itself is integrated with the concrete inside the column member.

Therefore, it is possible to prevent the concrete inside and outside the mesh-shaped tremi pipe 4 from being separated, and the mesh-shaped tremi pipe 4 itself serves as a reinforcing material, contributing to the increase in tensile strength and ductility of the column member.

In particular, in the case of the mesh-shaped tremi tube 4 formed of metal lath or wire mesh, the cross-sectional shape can be freely deformed, so that it can be easily installed even in a space where the upper space of the column member is narrow.

In the case of PSRC pillars or CFT pillars that are pre-assembled at the factory, the mesh-shaped tremi tube 4 can be pre-attached at the factory. Accordingly, it is possible to shorten the working time during on-site concrete pouring work.

The mesh-shaped tremi pipe 4 is preferably provided with a lower end spaced apart from the lower surface of the column member by a predetermined distance so that the concrete can be smoothly discharged downward.

It is preferable that the mesh size of the mesh-shaped tremi pipe 4 is less than or equal to the maximum size of the aggregate of concrete to be poured.

When the size of the mesh is too large, the aggregate may be discharged through the mesh and fall, thereby causing material separation.

Even if the concrete paste flows out through the mesh, it does not fall and flows along the outer circumferential surface of the mesh-shaped tremi tube 4 and is naturally filled from the lower part of the column member.

As described above, part of the concrete poured during concrete filling flows out through the mesh to the outside and flows down the outer wall of the mesh-shaped tremi pipe (4). And since the descent speed of the inner concrete is also controlled by the resistance of the mesh, it is possible to minimize the material separation of the concrete.

Conventionally, it was difficult to determine how much concrete is filled inside the pouring pipe in the pouring pipe of the closed section.

In contrast, the mesh-shaped tremi tube 4 can easily visually check the height of concrete supplied from the outside to the inside. Therefore, it is possible to control the concrete feed rate.

As shown in FIGS. 2 and 4, a plurality of discharge holes 41 may be formed on the outer circumferential surface of the mesh-shaped tremi tube 4.

When the concrete placement surface rises as the concrete is supplied into the pillar member, a plurality of discharge holes are provided on the outer circumferential surface of the mesh-shaped tremi tube 4 so that the concrete can be smoothly discharged through the discharge hole 41 immediately above the casting surface. (41) can be formed.

The plurality of discharge holes 41 may be formed to be spaced apart from each other in the height direction of the mesh-shaped tremi tube 4.

When the concrete placement surface rises according to the concrete placement, the pressure inside the mesh-shaped tremi pipe 4 increases in the vicinity of the placement surface, and the concrete is naturally discharged into the discharge hole 41 directly above the placement surface.

Of course, the concrete may be partially discharged through the discharge hole 41 and the mesh located inside the other installed concrete. Accordingly, since concrete is simultaneously supplied from both the upper and lower parts based on the pouring surface, it is possible to minimize material separation while the speed of concrete placement is very fast.

Since the conventional pipe for pouring concrete is sealed with a closed cross section, when the lower part of the pipe is buried inside the concrete and closed, the pressure inside the pipe rises rapidly. Accordingly, there is a concern that material separation may occur as concrete is discharged not only through the discharge hole in the upper part near the casting surface as well as through the discharge hole in the upper part far from the casting surface due to the reverse flow of the concrete. Therefore, in order to prevent this phenomenon, the pouring speed had to be lowered.

On the other hand, in the present invention, since the pressure difference inside and outside the mesh-shaped tremi pipe 4 is small, the concrete flows backward in the mesh-shaped tremi pipe 4 and the concrete is simultaneously discharged from the upper discharge holes 41 of different heights. Can be prevented.

In addition, since some of the concrete may be discharged not only through the discharge hole 41 but also through the mesh, the number of discharge holes 41 may be reduced compared to the existing closed-type pouring pipe.

4 is a side view showing a state in which a guide sleeve is installed in a mesh-shaped tremi tube.

As shown in FIG. 4, the lower end of the guide sleeve 5 for guiding the concrete supplied from the outside to the inside of the mesh-shaped tremi pipe 4 may be inserted in the upper portion of the mesh-shaped tremi pipe 4.

Usually, concrete is supplied from a concrete supply equipment such as a pump car or a concrete distributor to the mesh-shaped tremi pipe (4). However, when concrete is directly supplied from the supply pipe or corrugated pipe (7) provided at the end of the concrete supply equipment to the mesh tremi pipe (4), the entrance of the mesh tremi pipe (4) is narrow, so that the concrete goes into the mesh tremi pipe (4). It doesn't flow properly and can overflow.

Therefore, a guide sleeve (5) can be provided on the top of the mesh-shaped tremi pipe (4) to guide the concrete supplied from the supply pipe or corrugated pipe (7) connected to the end of the concrete supply equipment into the mesh-shaped tremi pipe (4). have.

Accordingly, even when the diameter of the mesh-shaped tremi pipe 4 is smaller than the diameter of the supply pipe or the corrugated pipe 7, it is possible to supply concrete smoothly.

The guide sleeve 5 is preferably formed of a fibrous material such as cotton wool so that it can be easily inserted into the mesh-shaped tremi tube 4 having a small diameter.

The upper part of the guide sleeve 5 can be fixed to the lower end of the supply pipe or the corrugated pipe 7 using a fixing band.

5 is a side cross-sectional view showing a concrete pouring process.

The process of pouring concrete using the buried-type pouring pipe for pouring pillars of the present invention will be described as follows.

First, as shown in (a) of FIG. 5, the concrete (C) under the column member is poured using the mesh-shaped tremi pipe (4).

And, as shown in (b) of Figure 5, by continuously injecting concrete (C) using the mesh-shaped tremi tube (4) to pour concrete (C) to the middle portion of the column member. At this time, the concrete (C) is poured into the column member through the discharge hole 41 of the mesh-shaped tremi tube 4.

Thereafter, as shown in (c) of FIG. 5, concrete (C) is poured to the top of the column member by continuously pouring concrete (C) using the mesh-shaped tremi pipe (4).

A photograph of a state in which concrete pouring is completed inside the pillar member is shown in FIG. 8.

6 is a perspective view showing a fixed state of a mesh-shaped tremi pipe by a fixing band, and FIG. 7 is a photograph showing an actual construction state of a mesh-shaped tremi pipe, and FIG. 8 is an actual concrete by the embedded-type pouring pipe for the present invention This is a picture showing the state of pouring.

As shown in FIGS. 6 and 7, the mesh-shaped tremi tube 4 can be manufactured by rolling a mesh net into a cylindrical shape and fixing it with a plurality of fixing bands 6.

Accordingly, the mesh-shaped tremi tube 4 can be manufactured easily and economically.

The fixing band 6 may be made of a steel band or the like for pipe connection. In this case, the fixing band 6 can be fixed to the mesh-shaped tremi tube 6 by bending the opposite ends to the outside and then bolting the protruding portion to the outside (FIG. 6).

The mesh-shaped tremi tube 4 may be installed with the upper part fixed to the main stiffener 2 of the column, and the lower part without separate fixing.

In this case, when the concrete is poured, the lower part of the mesh-shaped tremi pipe 4 flows naturally due to the concrete pouring pressure, and the concrete is poured tightly and evenly inside the column.

When the pillar member is a PSRC member that is a factory pre-assembled SRC joint, the main stiffener 2 may be composed of a-shaped steel.

When the column member is an RC member or a CFT column, the main stiffener 2 may be composed of a reinforcing bar.

1: pillar formwork
10: inner space
2: Main reinforcement
3: cross-shaped H beam
4: reticulated tremi tube
41: discharge hole
5: guide sleeve
6: fixed band
7: corrugated pipe
C: concrete

Claims (3)

The column member is provided in the longitudinal direction of the column member in the inner space 10 of the column formwork (1) for pouring concrete, and the upper part is fixed to the main reinforcement member (2) provided inside the column formwork (1), and the lower part is It is a tubular shape composed of a mesh body that is not separately fixed, and the mesh is rolled in a cylindrical shape and the top and bottom are open, and the size of the mesh is formed to be less than the maximum size of the aggregate of the concrete to be poured, and a plurality of discharge holes 41 are formed on the outer circumferential surface. As a result, most of the concrete injected through the upper part is discharged to the lower side through the inside of the mesh-shaped tremi pipe 4, while a part of the concrete containing paste flows down the outer circumferential surface through the mesh-shaped tremi pipe 4 ); And
A guide sleeve (5) whose lower portion is inserted into the upper portion of the mesh-shaped tremi pipe (4) to guide the concrete supplied from the outside to the inside of the mesh-shaped tremi pipe (4); Recessed pouring pipe for pouring pillars, characterized in that consisting of. delete delete

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