KR101500806B1 - The intelligent steel contrete structure - Google Patents

Abstract

The present invention relates to a reinforced concrete structure to be installed in a construction site. In the conventional reinforced concrete structure, since the styrofoam built in between the inner wall frame and the outer wall frame is constructed of a wall and a slab is installed thereon, the connection between the wall and the slab is integrated, Molds were generated by the back and there was a limit to be hot in the summer. The present invention relates to a reinforced concrete frame structure, in which an inner wall frame and a slab are integrally formed, the periphery thereof is surrounded by a styrofoam, the outer wall frame and the slab are formed by the reinforced concrete frame around the styrofoam, It is designed to provide a structure that allows cold water to flow, providing a warm intelligent reinforced concrete structure in winter and cool in summer.

Description

The intelligent steel contrete structure < RTI ID = 0.0 >

The present invention relates to a reinforced concrete structure to be installed in a construction site.

The present invention is to improve the arrangement method of styrofoam, which is a conventional heat insulating material, and to improve the heat insulation effect of a building and to solve problems such as condensation by arranging a metal pipe on the inner wall of concrete.

The background art of the present invention is to provide a building structure that is cool in summer and warm in winter by supplying cold water to a metal pipe installed in an inner reinforced concrete frame in the summer to reinforce the heat insulation to prevent the occurrence of condensation.
(Patent Document 1) Japanese Unexamined Patent Application Publication No. 2007-285086 (November 11, 2007)
Registration Practical Utility Model No. 20-0317947 (Jun. 27, 2003)

Currently, reinforced concrete architectural style is widely used, but there are the following problems.

First, insulation is not 100% complete. Slabs are not installed because of the presence of styropoles in reinforced concrete walls. In other words, the point where the wall and the slab are connected is not equipped with the styrofoam so that the insulation is not perfectly formed. So, for example, if you look at the slab floor in the snowy winter in the temperature range of 0 degree Celsius to 1 degree Celsius on the rooftops of ordinary multi-family houses or villas, you can see that the part corresponding to the wall is melting.

Second, in the Middle East, Africa, and the equatorial tropical regions, this type of architecture is hot and it is not easy to endure. Because, in the existing style of architecture, the external heat is transmitted as it is.

Then, there is a method of installing a gypsum board on a wall by one of the currently installed insulation methods. There is a defect that can not be received cold air which gives coolness and goodness when it is hot, though it can be seen to some extent in adiabatic effect.

In addition, the use of air-conditioners in the hot summer season is limited because the air-conditioner draws water vapor contained in the air, and when it is used for a long time, It became necessary.

To solve these problems, in order to construct a cool reinforced concrete structure in summer and a warm reinforced concrete structure in winter, it is divided into an inner frame and an outer frame to construct inner wall and slab from ground surface with reinforced concrete frame. I will wrap it. And, by wrapping this structure with reinforced concrete frame again, it is possible to construct 100% relative to existing reinforced concrete structure. In addition, it is possible to induce the structure of the building to cool down by supplying cold water, which can be supplied from groundwater in the summer, to the inner reinforced concrete frame by constructing the metal pipe as in the case of constructing the steel pipe during the inner frame construction.

The reinforced concrete structure designed in this way can cool the interior of the building by allowing cool water from underground water to flow through the inner frame in the summer and reduce the loss of heat generated from the interior building to the outside as much as possible during the winter. It is possible to provide the building without.

The present invention will be described in detail with reference to the accompanying drawings. FIG. 1 shows a conventional reinforced concrete structure. In this structure, when the installation position of the styrofoam is analyzed, the slab and the wall are separated from each other and the insulation is not perfect. As a result, the cold air pushed from the slab is pushed down by the inner reinforced concrete frame, There has been a problem of occurrence. Figure 2 shows the reinforced concrete structure of the present invention. The inner wall frame 3a and the outer wall frame 4a of the reinforced concrete structure are separately separated and connected to each other by fret ties. A metal pipe (5) is buried along the reinforcing bars (2) in the inner wall frame (3a) by embedding reinforcing bars in a checkerboard shape with the inner wall air conditioning (3a). As shown in FIG. 4, when the inner wall frame 3a is constructed, a metal pipe 5 extending from a cold water source such as groundwater is arranged in a checkerboard pattern with a lateral reinforcing bar and a vertical reinforcing bar, A metal pipe (5) is arranged along the first lateral reinforcement to the last longitudinal reinforcement positioned in the end direction of the lateral reinforcement, and the metal pipe (5) is arranged in the lower end direction of the last longitudinal reinforcement The metal pipe 5 is arranged along the last vertical reinforcing bar until it meets the second lateral reinforcing bar and the metal pipe 5 is arranged along the second lateral reinforcing bar until the first vertical reinforcing bar of the second lateral reinforcing bar meets the one And arranged in a zigzag form in the form of an "e" character. Each of the horizontal reinforcing bars and the vertical reinforcing bars and the metal pipe (5) are held together by a binding wire and fixed. The outside of the inner wall frame 3a having such a structure is enclosed by the styrofoam 1 and the outside of the styrofoam 1 is surrounded by the outside wall frame 4a. A checkerboard reinforcement is disposed in the outer wall frame 4a. The fret tie 7 connecting and supporting the inner wall frame 3a and the outer wall frame 4a is formed of a metal only as shown in Fig. 6, but a space 8 serving as a plastic cover is formed around the wall, . That is, when the formwork (euro foam) is applied to the inner wall and the outer wall, the space 8 for inserting the fret tie 7 must be inserted between the inner and outer molds, (7) is inserted and fixed in the space (8). The reason for inserting the space (8) is to remove the fray tie (7) after concrete construction to prevent the breakage of the insulation, thereby removing one element among various causes of condensation.

When the reinforcing bars provided in the inner wall or the inner slab are exposed to the outer wall 4a or the slab 6 at the time of constructing the next slab, the reinforcing bars 2 wrapped with the plastics 9 are used as shown in Fig. Thereby blocking the heat conduction between the inner wall 3a and the outer wall 4a. This is like the principle of cooking and holding plastic-wrapped handles with no problem for the hot frying pan we use in everyday life.

The reason why the metal pipe 5 is inserted into the inner wall frame 3a to flow cold water such as ground water is that the temperature in the inner wall frame 3a is compared with the temperature inside the structure to supply cold air, To be maintained. Particular attention should be paid to the technical tarket to control the quantity and the timing of the dike compared to the temperature in the structure so as not to reach the dew point which causes the dew condensation.

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1 is a conventional reinforced concrete structure in which a slab and a wall are connected to each other.

Fig. 2 is a reinforced concrete structure in which an inner frame and an outer frame are separated.

3 is a side view of a wall in which a metal pipe is inserted into an inner wall frame.

4 is a front view of the metal pipe inserted into the inner wall frame together with the reinforcing bars;

5 is a reinforcing bar heat-treated with a plastic cover.

Fig. 6 is a fret table for fixing the spacing between the molds.

FIG. 7 is a front view showing a fret tie interposed to fix the formwork in a space that maintains the spacing of the formwork.

8 is a side view of space and fret tie.

* Detailed description of symbols

1. Styrofoam

2. Reinforcement

3. Internal reinforced concrete frame

3a. Inner wall frame

4. External reinforced concrete frame

4a. Outer wall frame

4b. Outside wall frame or masonry wall

5. Metal tube

6. Slab

7. Furetai to hold Euroform and Euroform when you build a wall with form (Euroform)

8. Space for easy removal of flee ties inserted in the sidewalk wall when you finish the sidewalk process when building the wall with the formwork and later dismantle the form

9. Plastic cover wrapped around reinforcing steel for insulation

10. Ground surface

Claims (2)

In a reinforced concrete structure of a building composed of a concrete wall and a slab, a reinforcing bar (2) and a metal pipe (5) are arranged on an inner wall frame (3a), the inner wall frame (3a) is wrapped with the styrofoam And a space 8 is formed by a plastic cover in a fret tie 7 forming a frame 4a and connecting and supporting the inner wall frame 3a and the outer wall frame 4a. The intelligent reinforced concrete structure according to claim 1, wherein the reinforcing bars (2) are arranged horizontally and vertically in a checkerboard shape, and the metal pipes (5) are arranged in a " r " shape along the reinforcing bars.

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