KR101622549B1 - One-body type concrete form panel - Google Patents

Abstract

The present invention relates to a mold integrated with a finishing insulation material. The present invention is to provide a mold integrated with a finishing insulation material, which performs a role of a mold on both sides of a cured wall and forming multiple insulation layers. The mold integrated with a finishing insulation material includes: a pair of outer insulation material units installed on both sides of a space in which concrete is to be cured; a pair of inner insulation material units installed on the inner side of the pair of outer insulation material units and having a vacuum insulation area with the pair of outer insulation units; and a moving unit variably controlling the volume of the vacuum insulation area by moving the pair of inner insulation materials in a horizontal direction.

Description

{ONE-BODY TYPE CONCRETE FORM PANEL}

[0001] The present invention relates to a finished heat insulating material integrated die, and more particularly, to a finished heat insulating integrated die capable of forming multiple heat insulating layers on both sides of a cured wall.

Generally, a conventional method of forming a concrete structure generally includes an assembling step of assembling a reinforcing bar, a molding assembling step of enclosing the reinforcing bars and arranging the mold panels so as to face each other at a predetermined interval, And after the curing period has elapsed, a concrete panel is dismantled to form concrete concrete frame parts such as pillars, beams, walls, and floors.

In the conventional method, since the assembled form panel is disassembled when the respective concrete frame parts are formed and the work is carried out at the construction site, a mold disassembling period is required, and a mold disassembling period is required. And a yard for temporary storage of accessory materials.

In addition, in the conventional method of forming a concrete structure, it is necessary to perform a separate built-in work for insulation, soundproofing, and moisture-proofing for the user's comfortable use after completion of the building.

For this purpose, insulation, soundproofing, and moisture proofing material should be attached or installed on the surface of the concrete frame by using wood, steel or adhesive.

Therefore, in the conventional method, the steps such as heat insulation, soundproofing, and moisture-proofing are performed, leading to an increase in the construction period and the construction cost.

In recent years, it is required to develop a technique capable of simultaneously achieving finishing and insulation at the time of construction.

A concrete form using an integral body bolt which is integrally formed with a form (Patent Application No. 10-2012-0045821)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a finished heat insulating material integral die that can function as a mold on both sides of a wall to be cured and can form multiple heat insulating layers.

In a preferred embodiment, the present invention comprises a finished thermal insulator integral die.

The finishing heat insulating material integrated die comprises a pair of outer heat insulating parts disposed on both sides of the concrete curing expected space; A pair of inner heat insulating parts disposed inside the pair of outer heat insulating parts and forming the pair of outer heat insulating parts and the vacuum heat insulating area; And a moving part for moving the pair of inner heat insulating parts along a horizontal direction to variably control the volume of the vacuum insulating area.

The pair of outer heat insulating parts include a plurality of unit outer heat insulating materials arranged to be stacked on each other.

And each of the plurality of unit outer side heat insulating materials is fitted.

The pair of inner heat insulating parts include a plurality of unit inner heat insulating materials arranged to be stacked on each other.

Each of the plurality of unit inner heat insulating materials is connected to be slidably moved so as to variably control the volume of the vacuum insulating region.

A metal film having a predetermined thickness is formed on the outer surface of each of the plurality of unit inner heat insulating materials.

The moving unit includes screw bolts installed to rotate in each of the plurality of unit outer heat insulating materials.

Each of the screw bolts is screwed into the plurality of unit inner heat insulating materials disposed to face each other at the corresponding position.

When the screw bolt is rotated along the forward direction or the reverse direction, the unit inner heat insulating material is moved along the horizontal direction.

The moving unit further includes a rotation unit.

The rotation unit includes a support, a plurality of rotation motors provided on the support and having a motor shaft, and a controller for rotating the plurality of rotation motors.

The motor shaft of each of the plurality of rotation motors is detachably connected to the screw bolt installed in the plurality of unit outer heat insulating materials.

The controller is connected to a vacuum that forms a vacuum in the vacuum forming region.

In the plurality of unit inner heat insulating materials, temperature sensors are respectively installed.

The temperature sensors measure temperature values at the installation position and transmit the measured temperature values to the controller.

Wherein the controller is configured to average the temperature values to set a reference temperature value and drive the rotation motors so that the temperature values measured at the position reach the reference temperature value, Each of the screw bolts is rotated to horizontally move the plurality of unit inner heat insulating materials connected to the screw bolts to adjust the volume of the vacuum thermal insulating region at a corresponding position.

The present invention has the effect of forming multiple heat insulating layers in addition to acting as molds on both sides of the cured wall.

In addition, the present invention has the effect of forming a vacuum insulation layer by adjusting the volume of the vacuum insulation layer at both sides of the wall before concrete is cured, and arranging a heat insulation material on the outer side to increase heat insulation efficiency as well as acting as a barrier material .

FIG. 1 is a cross-sectional view showing a finished thermal insulating material integrated die of the present invention.
FIG. 2 is a view showing that a finished thermal insulating material integrated die of the present invention is disposed in a construction area.
FIG. 3 is a view showing the mark A of FIG. 2; FIG.
Fig. 4 is a perspective view showing a coupling relation between the unit outer insulator and the unit inner insulator according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a finishing thermal insulator integrated die of the present invention will be described with reference to the accompanying drawings.

FIG. 1 is a cross-sectional view showing a finished thermal insulating material-type workpiece of the present invention, FIG. 2 is a view showing that a finished thermal insulating material-integrated workpiece of the present invention is disposed in a construction area, FIG. Fig. 4 is a perspective view showing a coupling relation between the unit outer insulator and the unit inner insulator according to the present invention.

1 to 4, the finishing thermal insulating material integrated die of the present invention includes a pair of outer heat insulating portions 100 disposed on both sides of the concrete curing expected space a; A pair of inner heat insulating portions 200 disposed inside the pair of outer heat insulating portions 100 and forming the pair of outer heat insulating portions 100 and the vacuum heat insulating region b; And a moving unit 300 for variably controlling the volume of the vacuum adiabatic zone b by moving the pair of inner adiabatic members 200 along the horizontal direction.

The pair of outer heat insulating parts 100 include a plurality of unit outer heat insulating materials 110 arranged to be stacked on each other.

Each of the plurality of unit outer heat insulating materials 110 is fitted to each other.

The pair of inner heat insulating parts 200 include a plurality of unit inner heat insulating materials 210 arranged to be stacked on each other.

Each of the plurality of unit inner heat insulating materials 210 is connected to be slidably moved so as to variably control the volume of the vacuum insulating region b.

The unit protrusions 112 are formed on the upper ends of the plurality of unit outer heat insulating materials 110 and the coupling grooves 113 are formed on the lower ends thereof.

The engaging projections 112 are engaged with the other engaging grooves 113.

Sliding projections 212 are formed on the upper ends of the plurality of unit inner heat insulating materials 210 and sliding grooves (not shown) are formed on the lower ends thereof.

In addition, a metal film (not shown) having a predetermined thickness is formed on the outer surfaces of the plurality of unit inner heat insulating materials 210.

The sliding protrusion 212 is slidingly engaged with another sliding groove (not shown).

Meanwhile, the moving unit 300 includes screw bolts 310 installed to rotate in each of the plurality of unit outer heat insulating materials 110.

Each of the screw bolts 310 is screwed into the plurality of unit inner heat insulating materials 210 arranged to face each other at a corresponding position.

When the screw bolt 310 is rotated along the forward direction or the reverse direction, the unit inner heat insulating material 210 is moved along the horizontal direction.

At the end of the screw bolt 310, a cylindrical head 310a is formed.

The head 310a may be inserted into the stepped groove 111a formed in the first coupling hole 111 formed in the unit outer heat insulating member 110 and rotated in place.

The moving unit 300 further includes a rotation unit 400.

The rotation unit 400 includes a support 410 and a plurality of rotation motors 420 installed on the support 410 and having a motor shaft 421. The controller 420 rotates the plurality of rotation motors 420, (430).

The motor shaft 421 of each of the plurality of rotation motors 420 is detachably connected to the screw bolts 310 installed in the plurality of unit outer heat insulating materials 110.

Temperature sensors 440 are respectively installed in the plurality of unit inner heat insulating materials 210.

The temperature sensors 440 measure temperature values at the corresponding installation positions and transmit the measured temperature values to the controller 430. [

The controller 430 averages the temperature values to set a reference temperature value, drives the rotation motors 420 so that the temperature values measured at the corresponding position reach the reference temperature value, Each of the screw bolts 310 connected to the motor shaft 421 of the rotation motors 420 is rotated so that the plurality of unit inner heat insulating materials 210 connected to the screw bolts 310 are horizontally moved To adjust the volume of the vacuum adiabatic region (b) at the position.

Also, the controller 430 is connected to the vacuum 500 for forming a vacuum in the vacuum forming region a.

The vacuum 500 has a vacuum line 510 and the vacuum line 510 is connected to the vacuum forming area a.

The controller 430 controls driving of the vacuum 500 so as to achieve a predetermined degree of vacuum.

The present invention has the effect of forming multiple heat insulating layers in addition to acting as molds on both sides of the cured wall.

In addition, the present invention has the effect of forming a vacuum insulation layer by adjusting the volume of the vacuum insulation layer at both sides of the wall before concrete is cured, and arranging a heat insulation material on the outer side to increase heat insulation efficiency as well as acting as a barrier material .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by the scope of the appended claims and equivalents thereof.

It is to be understood that the foregoing embodiments are illustrative and not restrictive in all respects and that the scope of the present invention is indicated by the appended claims rather than the foregoing description, It is intended that all changes and modifications derived from the equivalent concept be included within the scope of the present invention.

100: outer insulator part
200: Inner insulator part
300:
400:
500: the jeans study

Claims (4)

A pair of outer heat insulating parts disposed on both sides of the concrete curing expected space;
A pair of inner heat insulating parts disposed inside the pair of outer heat insulating parts and forming the pair of outer heat insulating parts and the vacuum heat insulating area; And
And a moving part for moving the pair of inner heat insulating parts along a horizontal direction to variably adjust the volume of the vacuum insulating area,
Wherein the pair of outer heat insulating portions are formed in a substantially rectangular shape,
And a plurality of unit outer heat insulating materials arranged to be stacked on each other,
Wherein each of the plurality of unit outer heat insulating materials is fitted and fitted,
The pair of inner heat insulating portions
And a plurality of unit inner heat insulating materials arranged to be stacked on each other,
Wherein each of the plurality of unit inner heat insulating materials is connected to be slidably moved so as to variably control the volume of the vacuum insulating region
A metal film having a predetermined thickness is formed on an outer surface of each of the plurality of unit inner heat insulating materials,
The moving unit includes:
And screw bolts installed to rotate in each of the plurality of unit outer heat insulating materials,
Each of the screw bolts is screwed into the plurality of unit inner heat insulating materials arranged to face each other at the corresponding position,
Wherein when the screw bolt is rotated along the forward direction or the reverse direction, the unit inner heat insulating material is moved along the horizontal direction.
delete delete The method according to claim 1,
The moving unit may further include a rotation unit,
The rotation unit includes:
A support,
A plurality of rotation motors installed on the support rods and having motor shafts,
And a controller for rotating the plurality of rotation motors,
Wherein the motor shaft of each of the plurality of rotating motors is detachably connected to the screw bolt installed in the plurality of unit outer heat insulating materials,
Wherein the controller is connected to a vacuum to form a vacuum in the vacuum forming region.

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