KR20150060107A - Adiabatic concrete connecting structure and constructing method - Google Patents

Abstract

The present invention relates to adiabatic concrete connecting structure and method to form a structure by pouring concrete without a form. The adiabatic concrete connecting method comprises: a step of assembling horizontal and vertical wall re-bars on the top of foundation concrete and installing a pair of U-shaped guide supports on the top of the foundation concrete to face each other in a parallel manner; a step of installing a pair of adiabatic concrete forms (300) on the top of the pair of guide supports along the wall line in a symmetrical manner; a step of primarily applying a first stage of adiabatic concrete form (300) wherein a pair of unit adiabatic concrete forms (300) is fixated and fastened to each other over the entire section; a step of forming a pair of second stage unit adiabatic concrete forms (300) along the wall line and installing a second stage of adiabatic concrete form (300); a step of installing a final stage of adiabatic concrete form (300) as designed by repeating the above steps: and a step of forming an adiabatic concrete wall by pouring and curing concrete into a space between the adiabatic concrete form (300) and an adiabatic panel.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an insulating concrete structure,

The present invention relates to a heat insulating concrete structure and a method of constructing the same. More particularly, the present invention relates to a method of constructing a heat insulating concrete foam and connecting a heat insulating concrete foam through a connecting and fixing member at a construction site to form a concrete structure The present invention relates to a heat insulating concrete structure and a construction method.

Generally, walls of concrete structure for construction and civil engineering, which are composed of walls and slabs, are cured and dried after cement concrete is installed, and insulation is applied by adhering the heat insulating material to the outer surface or inner surface of the concrete wall.

That is, in order to construct a concrete wall first, a mold is installed on both sides of a steel assembly, a concrete wall is formed by pouring concrete, and various kinds of heat insulating materials are attached to the outer or inner side of the concrete wall, To form a concrete wall.

In the case of a slab, a concrete slab is formed by placing reinforcing bars on plywood or plastic formwork, and a concrete slab is formed by inserting a heat insulating material on a slab facing the outside such as an interlayer floor, an uppermost floor and a lowermost floor. .

These insulating concrete structures are the most common construction methods currently in common use.

However, the conventional heat insulating concrete structure is complicated in the construction process such as formwork, reinforcing work, and concrete after the construction, and the air may be delayed due to interfering with the subsequent process such as finishing work, There is a fear that a gap may be generated due to the failure to integrate with the frame, moisture penetrates through the gap, and mold is formed due to condensation in winter.

In addition, due to the use of steel or plywood formwork, waste materials are generated and processing costs are incurred. In order to form a concrete structure, skilled technical personnel such as non-work, steel bar, concrete work, wood work, The construction cost and the construction period are increased.

Korean Patent No. 10-1027618

SUMMARY OF THE INVENTION The present invention has been made to solve the conventional problems as described above, and has the following objectives.

The present invention relates to a method for constructing a structural body by connecting an adiabatic concrete foam part and connecting an adiabatic concrete foam through a connection fixing member at a construction site so as to connect the adiabatic concrete wall part without a separate formwork, Concrete structures and methods of construction.

In order to accomplish the above object, the present invention is implemented by the following embodiments.

The heat insulating concrete structure and method of the present invention

In constructing a wall structure in a concrete structure

Vertical and horizontal wall reinforcing bars are formed on the concrete foundation floor, and one pair of guide rails are positioned facing each other on the concrete foundation floor of the wall reinforcing bars. A pair of adiabatic concrete foam 300 is continuously installed on the guide base, and the adiabatic concrete foam bundled with the connection fixing pin 400 on the upper surface of the unitary adiabatic concrete foam 300 is stacked to form a wall form. The concrete is poured and cured between the heat-insulating concrete foam 300 constructed in a wall form so that the heat-insulating concrete foam 300 inside and outside the wall forms a heat-insulating concrete structure which also serves as a formwork and a thermal insulator.

In constructing the slab of the concrete structure

At the lower part of the slab, there are longitudinally formed concave grooved form heat insulating deck foam assembled at regular intervals, and the reinforced concrete or PC steel wire is formed on the concave groove and the thermal deck foam. Concrete is placed and cured on the upper part of the insulation deck foam to form a T-shaped concrete slab. Characterized in that the slab bottom heat-insulating deck foam forms an adiabatic concrete structure that also serves as a formwork and a thermal insulator.

The heat-insulating concrete foam 300 is characterized in that circular protrusions and T-shaped grooves bulging in the upper surface are formed at regular intervals and concave circular grooves and T-shaped grooves are formed at regular intervals on the lower surface.

The heat-insulating concrete foam 300 is formed by embedding a foam-type foam support in the heat-insulating concrete foam 300 according to the method of attaching the wall-finishing to the heat-insulating concrete foam 300.

Also, the heat-insulating concrete foam 300 is characterized in that the thickness can be increased in accordance with the installation area of the structure in consideration of the energy-saving design standard.

The connection fixing pin 400 is formed in a lattice type skeleton. Both ends of the connection fixing pin 400 are in the shape of a vertical plate, and the connection fixing pin 400 is connected and joined to extend the length.

In the case of installing the adiabatic concrete foam 300, the arrangement angle of the adiabatic concrete foam 300 may change, a corner may be formed, the wall structure may be branched, the wall structure may be joined to the column, The fixing brackets are inserted into circular protrusions formed on the upper surface of the heat insulating concrete foam 300 to bind the heat insulating concrete foams 300 together.

In constructing the wall of the structure

The foundation floor of the structure is formed of concrete, vertical and horizontal wall reinforcing bars are assembled on the upper part of the foundation, and a pair of U-shaped guide bases for fixing the heat-insulating concrete foam 300 are arranged in parallel on the upper surface of the foundation floor concrete .

The heat-insulating concrete foam 300 having the convex circular protrusions and the T-shaped grooves formed at regular intervals on the upper surface of the pair of guide supports and the lower surface formed with the concave circular grooves and the T-shaped grooves formed at regular intervals is symmetrically installed along the wall line step.

The connection pin 400 is inserted and installed at a predetermined interval in a T-shaped groove formed on the upper surface of the unitary insulating concrete foam 300 installed along the wall line, so that a pair of unitary insulating concrete foam 300 The first step is to construct the first-stage adiabatic concrete foam 300, which is mutually fixed and bound.

The protruding portion of the circular fixing protrusion formed on the upper surface of the unitary heat insulating concrete foam 300 of the first end heat insulating concrete and the connecting fixing pin 400 inserted into the T- The unitary heat-insulating concrete foam 300 is inserted into the circular recessed groove and the T-shaped groove to form a pair of the second-stage unitary heat-insulating concrete foam 300 along the wall line, and the two- (300) by inserting and fixing the connection fixing pin (400) in the T-shaped groove formed on the upper surface of the first insulating layer (300).

Installing the final-stage heat-insulating concrete foam 300 designed by repeating the above process.

After the final unit insulated concrete foam 300 is laminated and completed, the final heat-insulating concrete foam 300 is completed, and concrete is inserted and cured between the heat insulation panels of the heat-insulating concrete foam 300 to form an insulated concrete wall The method comprising the steps of:

The placement of the concrete between the adiabatic concrete foam 300 may be accomplished by placing the concrete between the adiabatic concrete foam 300 in the middle stage of the adiabatic concrete foam 300 so that the adiabatic concrete structure can be formed sequentially .

In constructing the slab of the structure

The step of installing the unitary thermal deck foam on the entire bottom plate area so that the joint joining protruding jaws of the both end portions of the form unitary thermal insulating deck foam are joined to each other at the bottom of the slab to form concave grooves with a predetermined width in the longitudinal direction

A reinforcing bar or a PC steel wire is installed in a concave groove having a predetermined width formed in the longitudinal direction of the assembled heat-insulating deck foam, and a reinforcing bar and a heating pipe are installed on the upper surface of the heat-

And placing the concrete on the concave groove and the upper surface of the heat-insulating deck foam so that the heat-insulating concrete foam 300 and the T-shaped concrete slab are integrated.

In the case of installing the adiabatic concrete foam 300, the arrangement angle of the adiabatic concrete foam 300 may change, a corner may be formed, the wall structure may be branched, the wall structure may be joined to the column, The fixing brackets drilled at predetermined regular intervals are inserted and installed in the circular protrusions formed on the upper surface of the heat insulating concrete foam 300 so that the heat insulating concrete foams 300 can be bound to each other .

The present invention has the following effects with the above-described configuration.

The heat insulating concrete structure and construction method according to the present invention can improve the parts transportability and reduce the transportation cost by making the adiabatic concrete foam part and assembling the heat insulating concrete foam as the wall through the connection fixing member, It is possible to form an adiabatic concrete wall to improve workability and work convenience.

In addition, the present invention can reduce the generation of construction waste due to the mold by allowing the concrete to be poured without a separate form since the wall is replaced by the mold, thereby reducing the cost of the work, and the concrete quality It is an invention having an effect of facilitating securing and enhancing the merchantability.

In addition, by reducing the generation of construction waste, it is possible to prevent the destruction of the natural environment and the pollution of the natural environment due to the production of the building timber.

1 is a perspective view showing an adiabatic concrete connection structure of the present invention,
Fig. 2 is a sectional view showing the adiabatic concrete connection structure of the present invention, Fig.
3 is a view showing a corner connection bracket mounted on a heat insulating concrete foam in an insulating concrete connection structure of the present invention,
4 is a view showing a connection fixing member in the adiabatic concrete connection structure of the present invention,
5 is a view showing a state where a connection fixing member and an extension member are connected to each other in the adiabatic concrete connection structure of the present invention,
6 is a cross-sectional view showing an embodiment of the connection fixing member of the heat insulating concrete connection structure of the present invention,
7 is a view showing a state in which the heat insulating deck portion of the heat insulating concrete connection structure of the present invention is provided,
FIG. 8 and FIG. 9 are block diagrams showing a method of constructing the adiabatic concrete connection structure of the present invention. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In the present invention, the adiabatic concrete foam 300 of a rectangular module is manufactured and transported in the factory, and the adiabatic concrete foam 300 is bound to the wall reinforcing bars 300 on the site by the connecting pin 400 And a method of constructing a wall of an adiabatic concrete structure by pouring and curing concrete between the adiabatic concrete foam 300 and a heat-insulating deck foam for forming a form are both manufactured in a factory, And a concrete is placed and cured on the heat-insulating deck foam 600 to constitute a slab of the heat-insulating concrete structure.

The concrete construction of the adiabatic concrete wall among the improvement techniques is as follows.

A pair of U-shaped guide bases 120 for fixing the heat-insulating concrete foam 300 are formed on the upper surface of the foundation bottom concrete in parallel with each other. And install it in a position facing it.

Convex circular projections 310P and T-shaped grooves 325 are formed at regular intervals on the upper surface of the pair of guide pedestals 120 and concave circular grooves 320P and T-shaped grooves 326 are formed at regular intervals The heat-insulating concrete foam 300 formed is symmetrically installed along the wall line.

Depending on the finishing installation method, a heat-insulating concrete foam 300 embedded with a built-in foam support may be installed.

The connection pin 400 is inserted and installed at a predetermined interval in a T-shaped groove formed on the upper surface of the unitary insulating concrete foam 300 installed along the wall line, so that a pair of unitary insulating concrete foam 300 First, the first-stage heat-insulating concrete foam 300 is fixed.

The protruding portion of the circular fixing protrusion formed on the upper surface of the unitary heat-insulating concrete foam 300 of the first-stage heat-insulating concrete and the connection fixing pin 400 inserted into the T-shaped groove is referred to as an upper portion of the second- A pair of second-stage unitary insulation concrete foam 300 is formed along the wall line by inserting the circular concave groove and the T-shaped groove in the lower surface of the unit-insulating-type concrete foam 300, The second end heat-insulating concrete foam 300 is constructed by inserting and fixing the connection fixing pin 400 into the T-shaped groove formed on the upper surface of the first and second heat-insulating members 300 and 300.

The above-described process is repeated to construct the final-stage heat-insulating concrete foam 300.

After the final unit insulated concrete foam 300 is laminated and completed, the finalized insulated concrete foam 300 is completed, and then concrete is inserted and cured between the heat insulation panels of the insulated concrete foam 300 to form an insulated concrete wall .

The concrete may be placed between the adiabatic concrete foam 300 and the adiabatic wall may be sequentially formed by inserting and curing concrete between the adiabatic panels at an intermediate stage of forming the adiabatic concrete foam 300.

The adhesion of the finishing material to the inside and the outside of the heat insulating concrete wall is a structure that is fixed and attached to the connection fixing pin 400 or the embedded foam support embedded in the heat insulating concrete foam 300.

The unitary insulating concrete foam 300 is a structure that can be adjusted according to the energy saving design standard such as thickening or thinning according to the site location in consideration of energy saving design standard.

The adiabatic concrete foam 300 is a structure that can freely change the shape of a heat-insulating concrete structure by changing a guide base to a straight line, a curved line, and a slant line.

The connection fixing pin 400 is formed in a lattice type skeleton, and both ends are in the shape of a vertical plate, and the length can be extended by connecting and joining the additional connection fixing pins 400.

In the case of installing the adiabatic concrete foam 300, the arrangement angle of the adiabatic concrete foam 300 may change, the corner may be formed, the wall structure may be branched, the wall structure may be joined to the column, When it is necessary to additionally bind, a fixing bracket punched at regular intervals in a circular shape is inserted and installed in a circular projection formed on the upper surface of the heat-insulating concrete foam 300 to connect the heat-insulating concrete foam 300 to each other. .

The heat-insulating concrete wall according to the present invention can be widely used because it is easier to carry the insulation material than the existing technology, and is easy to construct with a degree that the unskilled worker can construct in the field construction and has excellent heat insulation performance. have.

The concrete construction of the heat-insulating concrete slab of the present invention is as follows.

 The unitary thermal deck foam is formed in the entire bottom plate area so that the joint joining protrusions of both end portions of the combined unit heat-insulating deck foam 600 are joined to each other at the bottom of the slab to form concave grooves with a predetermined width in the longitudinal direction.

A reinforcing bar or a PC steel wire is installed in a concave groove having a predetermined width formed in the longitudinal direction of the assembled heat insulating deck foam, and a reinforcing bar and a heating pipe are formed on the upper surface of the heat insulating deck foam.

The concrete is placed and cured on the concave grooves and the upper surface of the heat-insulating deck foam to form an adiabatic concrete slab in which the heat-insulating concrete foam 300 and the T-shaped concrete slab are integrated.

The insulation deck foam is composed of a combination of unit insulation deck foam. The unit insulation deck foam has a rectangular shape with large grooves and small grooves on left and right, and Z-shaped fixing material 610 are symmetrical, and reinforcing bars or PC steel rods A concave groove and a connecting joint protruding jaw are formed to constitute a unit heat-insulating deck foam.

When the connecting joint protruding jaws of the lower end portions of the unitary heat-insulating deck foam are mutually joined and the unit heat-insulating deck foam is sequentially installed in the transverse direction, a concave groove having a constant width is formed between the heat-insulating deck product and the heat-

The bottom finishing material of the adiabatic concrete slab is fixed and attached to the Z-type fixing material.

The unit insulation deck foam can be adjusted to meet energy saving design standards by thickening or thinning depending on the site location in consideration of energy saving design standard.

The heat-insulating concrete slab according to the present invention is a heat-insulating deck foam for use with a heat insulating material, and is easy to construct because of its small weight and has a smaller weight than a solid concrete slab with a T-shaped slab structure.

In addition, it can be widely used because it has advantages such as increase of insulation effect and reduction of interlayer noise by integrating insulation and structure.

Since the heat-insulating concrete structure composed of the heat-insulating concrete wall and the heat-insulating concrete slab is used both as a mold and a heat-insulating material for each structure, the heat-insulating deck foam serves as a formwork and a heat insulating material without a separate formwork system in the concrete construction, And the insulation effect is increased by integrating the structure and the heat insulating material.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

120: Guide bearing 300: Insulating concrete foam
400: connection fixing member 600: adiabatic tech foam

Claims (11)

In constructing a wall structure in a concrete structure
Vertical and horizontal wall reinforcing bars are formed on the concrete foundation floor, and one pair of guide rails are positioned facing each other on the concrete foundation floor of the wall reinforcing bars. A pair of adiabatic concrete foam 300 is continuously installed on the guide base, and the adiabatic concrete foam bundled with the connection fixing pin 400 on the upper surface of the unitary adiabatic concrete foam 300 is stacked to form a wall form. Wherein the concrete is poured and cured between the insulated concrete foam (300) constructed in the form of a wall so that the insulated concrete structure (300) which serves both as a formwork and a thermal insulator is formed rescue.
In constructing a slab of a concrete structure
At the lower part of the slab, there are longitudinally formed concave grooved form heat insulating deck foam assembled at regular intervals, and the reinforced concrete or PC steel wire is formed on the concave groove and the thermal deck foam. Concrete is placed and cured on the upper part of the insulation deck foam to form a T-shaped concrete slab. Wherein the slab bottom insulating deck foam forms an adiabatic concrete structure that also serves as a formwork and a thermal insulator.
The method of claim 1, wherein
Wherein the adiabatic concrete foam (300) is formed with circular protrusions and T-shaped grooves that are bulged on the upper surface at regular intervals, and concave circular grooves and T-shaped grooves are formed at regular intervals on the lower surface.
The method of claim 3, wherein
Characterized in that the heat-insulating concrete foam 300 is formed by embedding a foam-type foam support in the heat-insulating concrete foam 300 according to the wall-finishing method for constructing the heat-insulating concrete foam 300.
4. The method according to claim 3 or 4, wherein
Wherein the heat-insulating concrete foam (300) is capable of increasing thickness according to the installation area of the structure in consideration of energy saving design standards.
The method of claim 1, wherein
Wherein the connection fixing pin (400) is formed in a lattice type skeleton, and both ends of the connection fixing pin (400) are in the form of a vertical plate and the additional connection fixing pins (400) are connected and joined to extend the length.
The method of claim 1, wherein
In the case of installing the adiabatic concrete foam 300, the arrangement angle of the adiabatic concrete foam 300 may change, the corner may be formed, the wall structure may be branched, the wall structure may be joined to the column, Wherein the fixing brackets are inserted into circular protrusions formed on the upper surface of the heat-insulating concrete foam 300 to bind the heat-insulating concrete foams 300 when the fixing brackets need to be further bound. Connection structure.
In constructing the wall of the structure
The foundation floor of the structure is formed of concrete, vertical and horizontal wall reinforcing bars are assembled on the upper part of the foundation, and a pair of U-shaped guide bases for fixing the heat-insulating concrete foam 300 are arranged in parallel on the upper surface of the foundation floor concrete .
The heat-insulating concrete foam 300 having the convex circular protrusions and the T-shaped grooves formed at regular intervals on the upper surface of the pair of guide supports and the lower surface formed with the concave circular grooves and the T-shaped grooves formed at regular intervals is symmetrically installed along the wall line step.
The connection pin 400 is inserted and installed at a predetermined interval in a T-shaped groove formed on the upper surface of the unitary insulating concrete foam 300 installed along the wall line, so that a pair of unitary insulating concrete foam 300 The first step is to construct the first-stage adiabatic concrete foam 300, which is mutually fixed and bound.
The protruding portion of the circular fixing protrusion formed on the upper surface of the unitary heat insulating concrete foam 300 of the first end heat insulating concrete and the connecting fixing pin 400 inserted into the T- The unitary heat-insulating concrete foam 300 is inserted into the circular recessed groove and the T-shaped groove to form a pair of the second-stage unitary heat-insulating concrete foam 300 along the wall line, and the two- (300) by inserting and fixing the connection fixing pin (400) in the T-shaped groove formed on the upper surface of the first insulating layer (300).
Installing the final-stage heat-insulating concrete foam 300 designed by repeating the above process.
After the final unit insulated concrete foam 300 is laminated and completed, the final heat-insulating concrete foam 300 is completed, and concrete is inserted and cured between the heat insulation panels of the heat-insulating concrete foam 300 to form an insulated concrete wall The method comprising the steps of:
The method of claim 8, wherein
The placement of the concrete between the adiabatic concrete foam 300 can be accomplished by placing the concrete between the adiabatic concrete foams 300 in the middle stage of the adiabatic concrete foam 300 so that the adiabatic concrete structure can be formed sequentially Construction method of insulation concrete connection structure which is characterized
In constructing the slab of the structure
The step of installing the unitary thermal deck foam on the entire bottom plate area so that the joint joining protruding jaws of the both end portions of the form unitary thermal insulating deck foam are joined to each other at the bottom of the slab to form concave grooves with a predetermined width in the longitudinal direction
A reinforcing bar or a PC steel wire is installed in a concave groove having a predetermined width formed in the longitudinal direction of the assembled heat-insulating deck foam, and a reinforcing bar and a heating pipe are installed on the upper surface of the heat-
Inserting the heat-insulating concrete foam 300 and the T-shaped concrete slab integrally with the concrete by placing the concrete on the concave grooves and the upper surface of the heat-insulating deck foam.
In the case of installing the adiabatic concrete foam 300, the arrangement angle of the adiabatic concrete foam 300 may change, the corner may be formed, the wall structure may be branched, the wall structure may be joined to the column, The fixing brackets punched at predetermined regular intervals are inserted and installed in the circular protrusions formed on the upper surface of the heat insulating concrete foam 300 so that the heat insulating concrete foam 300 can be bound to each other. Construction method of insulation concrete connection structure

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