KR101651864B1 - Siedwall insulation structure of apartment - Google Patents

Abstract

The present invention provides a side wall insulation structure of an apartment house. The side wall insulation structure of an apartment house comprises: a wall forming an outer wall of an apartment house; a plurality of insulation layers formed inside the wall; a geothermal energy collection unit installed in the wall and collecting geothermal energy; and an insulation control unit supplying the geothermal energy collected to enable a difference between the outer temperature and the inner temperature of the wall to be within an error range to the insulation layers.

Description

[0001] SIEDWALL INSULATION STRUCTURE OF APARTMENT [0002]

More particularly, the present invention relates to a multi-layer heat insulating layer inside a wall constituting an outer wall of a multi-storeyed house, and also to collect heat generated by geothermal and hot water supply by a separate collecting device And then supplying the heat insulating layer to the insulating layer to secure the heat insulating performance of the room.

In recent years, researches on insulation and eco-friendly construction methods have been increasing for the purpose of preventing global warming and protecting the environment.

Generally, when a wall of a building is to be installed, reinforcing bars are vertically and horizontally arranged at a portion where a wall is to be formed, and the formwork is installed parallel to both sides of the reinforced bars, and then concrete is placed between parallel- And then the insulating material is installed on the inner side and / or the outer side of the cured concrete wall surface and finished with the finishing material to complete the wall.

In the concrete example of the construction of the concrete structure, the formwork is installed parallel to the outdoor side and the indoor side with the reinforced reinforced concrete being centered, and the parallel formwork is fixed by the flat tie so that the parallel formwork can be kept constant at a predetermined interval Concrete is laid between the formwork to form a wall.

Next, with the heat insulating material attached to the outer surface of the cured concrete, the outer surface of the heat insulating material is finished with a finishing material.

However, since the conventional heat insulating material of the concrete wall is constructed to adhere the heat insulating material to the outer wall or the inner wall of the building wall, it is vulnerable to fire or shock, and it may take a lot of maintenance and repairing cost. Especially, And thus, when the heat insulating material is broken, it is easily exposed to harmful substances to the human body.

Patent Application No. 10-2011-0143324

It is an object of the present invention to provide a multi-layer heat insulating layer inside a wall constituting an outer wall of a multi-storeyed house, to collect heat generated by geothermal and hot water supply by a separate collecting device, And a side wall insulated structure for a side wall of a building.

Another object of the present invention is to provide a sidewall insulation structure for a sidewall of a house which is capable of detachably installing a plurality of heat insulation layers on the indoor side and informing the user of the replacement period of the heat insulation layers so that the sidewall insulation structure can be easily replaced.

It is still another object of the present invention to provide a solar cell side wall insulation structure in which solar cells are installed in the outer wall itself in winter so that thermal energy can be accumulated through natural light and supplied to each heat insulating layer.

In a preferred embodiment, the present invention provides a multi-housing side wall insulation structure.

The sidewall insulation structure of the sidewall includes a wall constituting an outer wall of the sidewall; A plurality of heat insulating layers formed inside the wall; A geothermal trap installed in the wall to collect geothermal heat; And an adiabatic control unit for supplying the geothermal heat to the plurality of heat insulating layers so that the difference between the outside temperature and the inside temperature of the wall reaches an established error range.

The plurality of heat insulating layers are formed inside the wall with a gap therebetween, and include heat insulating space portions in which a vacuum space is formed, and vacuum providing devices that individually provide a vacuum to the heat insulating spaces.

On the inner wall of the vacuum space, an embossing protrusion formed of a heat insulating material is formed.

The heat insulating space portions communicate with each other through a plurality of connection flow paths.

In the plurality of connection channels, a valve is provided, and vacuum sensors for measuring the degree of vacuum are installed in each of the heat insulating spaces.

Wherein the heat insulating control unit controls the degree of vacuum of one of the heat insulating space parts to be the same as that of the other heat insulating space parts when the degree of vacuum of one of the heat insulating space parts is lower than that of other heat insulating space parts, The valves are opened and closed to provide vacuum.

Air layers are formed around the outer periphery of the plurality of heat insulating layers.

The inner side wall of the air layers may be provided with a heating element that receives external heat and generates heat.

The geothermal heat collecting unit includes a geothermal absorber buried in the ground and absorbing the geothermal heat in the ground, heat-conducting pipes connected to the air layers of the geothermal absorber and the plurality of heat insulating layers, Closing valves for opening and closing the heat flow path of each of the heat conduction pipes under the control of the control unit.

The outer surface of the wall is provided with a solar absorbing part for absorbing heat energy through solar heat and heat transfer pipes for transmitting the heat energy absorbed from the solar absorbing part to each of the heat conductive pipes.

Inside the wall, a plurality of unit vacuum lines extending from the plurality of heat insulating spaces are formed in a lattice shape.

In the present invention, a multi-layered heat insulating layer is formed inside a wall constituting an outer wall of a multi-unit house, and the heat generated by the geothermal and hot water supply is collected by a separate collecting device and supplied to the corresponding heat insulating layer, .

Further, according to the present invention, a plurality of heat insulating layers are detachably installed on the indoor side, and the replacement period of the heat insulating layers is informed to the user, thereby facilitating the replacement.

Further, the present invention has the effect of providing solar cells in the outer wall itself in winter, accumulating thermal energy through natural light, and supplying them to the respective heat insulating layers.

FIG. 1 is a perspective view showing a side wall insulation structure of the present invention. FIG.
2 is a cross-sectional view showing a configuration of an insulating portion according to the present invention.
3 is a cross-sectional view showing a configuration of a heat insulating portion in which an air layer according to the present invention is formed.
4 is a cross-sectional view showing an example in which a solar absorber is installed on an outer surface of a wall according to the present invention.
FIG. 5 is a plan view showing a plurality of unit vacuum lines extending from a plurality of insulating spaces. FIG.

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

FIG. 2 is a cross-sectional view showing the construction of the heat insulating part according to the present invention, FIG. 3 is a sectional view showing the construction of the heat insulating part in which the air layer according to the present invention is formed, FIG. 4 is a sectional view showing an example in which a solar absorber is installed on an outer surface of a wall according to the present invention, and FIG. 5 is a plan view showing a plurality of unit vacuum lines extending from a plurality of insulating spaces.

1 to 5, the thermal insulation structure of a sidewall of a sidewall of the present invention comprises a wall 100 constituting an outer wall of a sidewall, a plurality of heat insulation layers 200 formed inside the wall 100, The geothermal heat collecting unit 300 installed in the heat insulating layer 100 and the geothermal heat collecting unit 300 collects the geothermal heat so that the difference between the outside temperature and the inside temperature of the wall 100 reaches an established error range, And a heat-insulating control unit 400 for supplying the heat-insulating material to the heat-

The wall 100 has a mounting hole 110 in which a plurality of heat insulating layers 200 are inserted.

The mounting hole 110 may be hermetically sealed by coupling the cover 120.

Although not shown in the drawings, the plurality of heat insulating layers 200 may be concave-convex bonded to each other.

Further, a separate heat insulating member may be interposed between the plurality of heat insulating layers 200.

Further, the plurality of heat insulating layers 200 may be embedded in a vacuum case which forms a separate vacuum. In this case, the case is fitted to the mounting hole 110 formed in the wall body 100.

In addition, the heat insulating spacers 250 may be provided between the heat insulating layers 200 to maintain a gap therebetween.

Both ends of the insulating spacers 250 are inserted and fixed to the outer surface of each of the heat insulating layers 200 facing each other.

The plurality of heat insulating layers 200 are formed in the wall 100 to be spaced apart from each other and have heat insulating space portions 210 in which a vacuum space 201 is formed, (Not shown).

On the inner wall of the vacuum space 201, an embossed protrusion (not shown) formed of a heat insulating material is formed.

The heat insulating space portions 210 communicate with each other through a plurality of connection flow paths 230.

A valve (not shown) is provided in the plurality of connection flow paths 230.

In each of the heat insulating spaces 210, vacuum sensors 240 for measuring a degree of vacuum are installed.

When the degree of vacuum of one of the heat insulating space parts 210 of the heat insulating space parts 210 is lower than that of other heat insulating space parts 210, 210 are equal to the degree of vacuum of the other heat-insulating space portions 210 by opening and closing the valves to provide a vacuum.

Air layers 280 are formed around the outer periphery of the plurality of heat insulating layers 200.

The inner side wall of the air layers 280 may be provided with a heating element (not shown) which generates heat by receiving external heat.

The geothermal heat collecting unit 300 includes a geothermal absorber 310 buried in the ground and absorbing the geothermal heat in the ground and an air layer 280 connected to the geothermal absorber 310 and the plurality of the heat insulating layers 200 Closing valves 330 installed at the heat conduction pipes 320 for opening and closing the respective heat transfer paths of the heat conduction pipes 320 under the control of the heat insulating control unit 400, ).

The outer surface of the wall 100 is provided with a solar absorbing part 510 for absorbing heat energy through solar heat and heat transfer pipes for transferring the heat energy absorbed from the solar absorbing part 510 to each of the heat conductive pipes 520 are provided.

Inside the wall 100, a plurality of unit vacuum lines 202 extending from the plurality of heat insulating spaces 200 are formed in a lattice shape.

According to the above-described structure and operation, in the embodiment of the present invention, a multi-layer heat insulating layer is formed in the wall constituting the outer wall of the apartment house, and the heat generated by the geothermal and hot water supply is collected by a separate collecting device And the heat insulating performance of the room can be secured by supplying the heat insulating layer.

In the embodiment of the present invention, a plurality of heat insulating layers are detachably installed on the indoor side, and the replacement period of the heat insulating layers is informed to the user so that the replacement can be easily performed.

In the embodiment according to the present invention, solar cells are installed in the outer wall itself in winter, and thermal energy is accumulated through natural light and supplied to each heat insulating layer.

The reference symbol '10' is reinforcing steel.

As described above, the concrete housing side wall insulation structure of the present invention has been described. However, it is apparent that various modifications are possible within 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: Wall
200: insulating layer
300: Geothermal collecting part
400: adiabatic control unit

Claims (4)

A wall constituting the outer wall of the apartment house;
A plurality of heat insulating layers formed inside the wall;
A geothermal trap installed in the wall to collect geothermal heat; And
And a heat insulation control unit for supplying the geothermal heat to the plurality of heat insulating layers so that the difference between the outside temperature and the inside temperature of the wall reaches an established error range,
Wherein the plurality of heat insulating layers comprise:
Insulating spaces formed inside the wall at intervals to form a vacuum space,
And vacuum providing means for individually providing a vacuum to the insulating spaces,
On the inner wall of the vacuum space,
An embossed protrusion formed of a heat insulating material is formed,
Air layers are formed on outer peripheries of the plurality of heat insulating layers,
The geothermal heat collecting unit,
A geothermal absorber embedded in the earth and absorbing geothermal heat in the earth;
And heat conduction pipes connected to the air layer of each of the plurality of heat insulating layers and the geothermal absorber.
Closing valves for opening and closing a heat flow path of each of the heat conduction pipes under the control of the heat insulating control unit
Wherein the inner side wall of the air layer is further provided with a heating element that receives external heat and generates heat.
delete The method according to claim 1,
The heat insulating space portions communicate with each other through a plurality of connection flow paths,
A valve is provided in the plurality of connection channels,
Vacuum sensors for measuring the degree of vacuum are installed in each of the heat insulating spaces,
The heat insulating control unit
Wherein when the degree of vacuum of one of the heat insulating space parts is lower than that of other heat insulating space parts, the valves are opened and closed so that the degree of vacuum of the one heat insulating space parts becomes the same as the degree of vacuum of the other heat insulating space parts, Wherein the side wall insulation structure is provided with a side wall insulation structure. delete

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