KR101651868B1 - Insulation system - Google Patents

Abstract

The present invention provides an insulation system for construction work. The insulation system for construction work comprises: a base unit forming an external wall and a rooftop layer of a building, and made of concrete; an insulation unit arranged to slide and be inserted into the base unit, arranged to be grid-shaped, and having a plurality of unit insulation units having a vacuum space therein; and an insulation control unit variably controlling a vacuum degree formed in each vacuum space of a plurality of unit control units in accordance with inside and outside temperatures at a plurality of positions of the base unit.

Description

{INSULATION SYSTEM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a construction insulation system, and more particularly, to a construction insulation system capable of locally dividing a heat insulation area into a plurality of areas in a wall and a roof of a building.

Generally, the insulation waterproofing treatment of a building refers to a construction having a waterproof function for keeping cool in the summer and warm in winter, and a waterproof function for preventing leakage of rainwater to the building.

The waterproofing of a building, in its broadest sense, includes waterproofing of the roof and the entire exterior wall of the building, but it is generally preferred that the roof, the parapet and the ceiling, Refers to the treatment of fragile parts.

In the government policy business area, the government occupies more construction part in terms of energy saving and expects to save energy by applying the construction part which expects energy effect to design.

However, there is still a great need for leakage and insulation problems that are expected to be most effective in all construction materials.

Particularly, roofs, roofs, etc. are required to be treated with special waterproofing because they can intensively penetrate rainwater.

In existing concrete structures, although roofs and the like are under the worst environmental conditions exposed directly to the external environment, waterproof materials actually applied to the roofs are difficult to secure the insulation performance.

In winter and during the summer, the higher the water content according to the concrete temperature and the water content according to the moisture content of the base surface, the higher the occurrence frequency of defects due to the adhesion property of the waterproofing material. That is, it is difficult to prevent the tearing phenomenon of the waterproof layer due to bubble phenomenon or breakage due to the steam pressure that is vaporized after the construction. Unless this problem is solved, it is very difficult to prevent swelling and breakage due to the moisture and condensation of the waterproof layer.

Patent Application No. 10-2006-0056644

SUMMARY OF THE INVENTION It is an object of the present invention to provide a building insulation system capable of locally controlling heat insulation by partitioning a heat insulation area in a wall and a roof of a building into a plurality of areas.

In a preferred aspect, the present invention provides a building construction insulation system.

The building insulation system comprises: a base portion formed of concrete, forming an outer wall and a roof layer of a building; A heat insulating part slidingly disposed in the base part and having a plurality of unit heat insulating parts arranged in a lattice shape and having a vacuum space therein; And an adiabatic control unit for variably controlling a degree of vacuum formed in the vacuum spaces of the plurality of unit control units according to temperatures inside and outside at a plurality of positions of the base unit.

A mounting groove is formed in the base portion, and a sliding door for slidingly opening and closing the mounting groove is provided.

Wherein the heat insulating portion is slidably inserted into the mounting groove and includes a plurality of unit heat insulating portions and a plurality of unit heat insulating portions which are installed in the fixing portion in response to a control signal from the heat insulating control portion, And a vacuum supply unit connected through a plurality of vacuum lines so as to independently provide vacuum.

An auxiliary vacuum layer is further formed inside the fixing part, and the auxiliary vacuum layer is vacuumed through the vacuum providing part.

A plurality of metal pins to be fitted to the fixing portion are protruded from the inner side wall of the mounting groove.

The base portion is provided with a plurality of cylinders having axes to be expanded and contracted in accordance with the control signal of the heat insulating control portion.

The shaft is projected to the inside of the installation groove as it is expanded and contracted.

The plurality of metal fins are connected to shafts of the plurality of cylinders protruded under the control of the heat insulating control unit, and after the heat insulating part is located in the installation groove, the plurality of metal fins are protruded to be formed As shown in Fig.

The heat insulating control unit includes a heating unit and a cooling unit.

The plurality of metal pins are connected to the heating unit and the cooling unit.

The adiabatic control unit controls the driving of the heating unit and the cooling unit so that the temperature in the vacuum space in the plurality of unit heat insulating units reaches a set reference temperature, and variably controls the temperature of each of the plurality of metal pins.

The heating unit includes a heating coil installed inside the plurality of metal fins to heat the plurality of metal fins.

The cooling unit includes a cooling coil installed inside the plurality of metal fins to cool the plurality of metal fins.

The heat insulating control unit is connected to an operating switch for selecting one of the heating coil and the cooling coil.

The plurality of unit heat insulating units may include a heat insulating body formed with the vacuum space, and a plurality of partition plates formed in the vacuum space, forming a plurality of layers in the vacuum space and piercing holes that are communicated with each other.

The present invention has the effect of locally controlling adiabatic heat by dividing the heat insulation area into a plurality of areas in the wall and roof of the building.

1 is a perspective view showing the construction of a construction insulation system of the present invention.
2 is a perspective view showing the unitary thermal insulation unit according to the present invention.
3 is a cross-sectional view illustrating the construction of the construction insulation system of the present invention.
4 is a view showing a configuration of a metal pin according to the present invention.

Hereinafter, a construction insulation system of the present invention will be described with reference to the accompanying drawings.

FIG. 1 is a perspective view showing the construction of a construction insulation system according to the present invention, FIG. 2 is a perspective view showing a unitary insulation unit according to the present invention, FIG. 3 is a sectional view showing the construction of a construction insulation system according to the present invention, Is a diagram showing the configuration of the metal pin according to the present invention.

1 to 4, the building construction insulation system of the present invention includes an outer wall and a roof layer of a building and includes a base portion 100 formed of concrete, a slidably inserted and arranged portion of the base portion 100, (200) having a plurality of unit heat insulating portions (210) arranged in a lattice shape and having a vacuum space formed therein, and a heat insulating portion (200) having a plurality of unit heat insulating portions And an adiabatic control unit 300 for variably controlling the degree of vacuum formed in the vacuum space 201 of each unit control unit.

In this case, the base portion 100 is provided with a mounting groove 110, and a sliding door 120 for slidingly opening and closing the mounting groove 110 is provided.

The sliding door 120 may be inserted through a sliding hole 111 formed at one side of the base part 100 to open and close the installation groove 110.

The heat insulating part 200 includes a fixing part 220 slidably inserted into the mounting groove 110 and provided with the unit thermal insulating parts 210 and a control signal from the heat insulating control part 300 And a plurality of vacuum lines 231 connected to the plurality of unit heat insulating parts 210 through the plurality of vacuum heaters 231 so as to independently provide vacuum to the vacuum spaces 201 of the plurality of unit heat insulating parts 210. [ (230).

Although not shown in the drawings, the auxiliary vacuum layers may be further formed in the multi-layer or lattice-like side in the fixing part 220, and the auxiliary vacuum layer may be formed by forming a vacuum through the vacuum providing part 230 .

A plurality of metal pins 600 to be fitted to the lower end of the fixing portion 220 are protruded from the lower end wall of the mounting groove 110.

The base unit 100 is provided with a plurality of cylinders 500 having axes 510 that are expanded and contracted according to a control signal of the adiabatic control unit 300.

The shaft 510 is projected to the inside of the installation groove 110 as it is expanded and contracted.

The plurality of metal pins 600 are connected to the axis 510 of each of the plurality of cylinders 500 protruded under the control of the heat insulating control unit 300.

After the heat insulating portion 200 is positioned in the installation groove 110, the plurality of metal pins 600 protrude and are fitted into a plurality of metal grooves 221 formed in the fixing portion.

The heat insulating control unit 300 includes a heating unit 700 and a cooling unit 800.

The plurality of metal pins 600 are connected to the heating unit 700 and the cooling unit 800.

The heat insulating control unit 300 controls the driving of the heating unit 700 and the cooling unit 800 so that the temperature in the vacuum space 201 within the plurality of unit heat insulating units 210 reaches a set reference temperature And the temperature of each of the plurality of metal pins 600 is variably controlled.

The heating unit 700 includes a heating coil 710 installed inside the plurality of metal pins 600 to heat the plurality of metal pins 600.

The cooling unit 800 includes a cooling coil 810 installed inside the plurality of metal pins 600 to cool the plurality of metal pins 600.

Here, the heat insulating portion 200 according to the present invention includes a cover 250 formed of a heat insulating material. The cover 250 is a structure for enclosing the unitary insulation unit 210 according to the present invention.

The cover 250 is disposed at the top of the sliding door 120.

A first temperature sensor 310 is provided at an upper end of the sliding door 120 to measure an external temperature and transmit the external temperature to the heat insulation controller 300.

The first temperature sensor 310 measures the outside temperature, and the second temperature sensor 320 measures the inside temperature.

A second temperature sensor 320 for measuring the temperature of the vacuum space 201 and transmitting the temperature to the heat insulation controller 300 is installed in the vacuum space 201 of each of the unit heat insulating parts 210.

The vacuum space 201 is provided with a vacuum sensor 330 for measuring the degree of vacuum in the vacuum space 201 and transmitting the degree of vacuum to the adiabatic control unit 300.

In addition, the vacuum lines 221 are provided with valves 232 that can be opened or closed under the control of the adiabatic control unit 300 to adjust the degree of vacuum in the vacuum space.

A seal 240 is provided to seal between the edge of the cover 250 and the sliding door 310.

The heat insulating control unit 300 is connected to an operation switch (not shown) for selecting one of the heating coil 710 and the cooling coil 810.

The plurality of unit heat insulating portions 210 may include an insulating body in which the vacuum space 201 is formed and a plurality of unit heat insulating portions 210 that are provided in the vacuum space 201 to form multiple layers in the vacuum space 201, And has a plurality of partition plates 211 through which holes (not shown) are perforated.

Through the above-described structure and operation, the embodiment according to the present invention can locally perform heat insulation control by dividing the heat insulation area in the wall and the roof of the building into a plurality of areas.

As described above, the concrete construction heat insulation system of the present invention has been described. However, it is apparent that various modifications can 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: Base portion
200:
300: adiabatic control unit

Claims (4)

A base part forming an outer wall and a roof layer of the building and formed of concrete;
A heat insulating part slidingly disposed in the base part and having a plurality of unit heat insulating parts arranged in a lattice shape and having a vacuum space therein; And
And a heat insulation controller for variably controlling a degree of vacuum formed in a vacuum space of each of the plurality of unit heat insulating parts according to temperatures inside and outside at a plurality of positions of the base part,
Wherein the base portion is provided with a mounting groove, a sliding door for slidingly opening and closing the mounting groove is provided,
The heat-
A fixing unit slidably inserted into the installation groove and provided with the plurality of unit heat insulating units,
And a vacuum supply unit installed in the fixing unit to receive a control signal from the adiabatic control unit and connected through a plurality of vacuum lines so as to independently supply a vacuum to the vacuum spaces of the plurality of unit heat insulating units,
A plurality of metal fins which are fitted and fixed to the fixing portion are protruded from the inner side wall of the mounting groove,
The base is provided with a plurality of cylinders having axes to be expanded and contracted in accordance with a control signal of the heat insulating control unit,
The shaft is projected to the inside of the installation groove as it is expanded and contracted,
Wherein the plurality of metal fins comprises:
A plurality of cylinders which are connected to the shafts of the plurality of cylinders protruded under the control of the heat insulating control unit,
After the heat insulating portion is placed in the installation groove,
Wherein the plurality of metal fins are protruded and fitted into a plurality of metal grooves formed in the fixing portion.
delete The method according to claim 1,
An auxiliary vacuum layer is further formed inside the fixing portion,
Wherein the auxiliary vacuum layer is formed with a vacuum through the vacuum supply unit.
delete

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