KR101822006B1 - Dual Vacuum Insulation Block - Google Patents

Abstract

The present invention relates to a dual vacuum insulation block which dually inserts vacuum insulators to be overlapped to block a linear heat bridge, continuously maintain insulation by one vacuum insulator even if the other vacuum insulator is destroyed during construction, and prevent damage to the vacuum insulators during construction. A second body into which a second vacuum insulator is inserted is arranged to be vertically and horizontally misaligned with respect to a first body into which a first vacuum insulator is inserted to dually overlap a prescribed area of the first vacuum insulator and the second vacuum insulator to maintain insulation performance as it is even if any one among the first vacuum insulator and the second vacuum insulator is broken. If a plurality of block bodies are connected, the linear heat bridge caused by a connection portion of the block bodies is blocked.

Description

Dual Vacuum Insulation Block}

More particularly, the present invention relates to a vacuum insulation block, and more particularly, to a vacuum insulation block, in which a vacuum insulation panel is interposed so as to be overlapped with each other to block a linear heat brick connection, and even if one vacuum insulation layer is broken during installation, And to prevent the breakage of the vacuum insulation material during construction.

Generally, the largest portion of the energy consumption of buildings is heat loss through the exterior walls of buildings. In order to prevent such heat loss, insulation is installed on the outer wall of the building.

Styrofoam, urethane foam, glass surface, rock surface, polyester foam, etc. are attached to the outer wall of the building to block the heat transmitted through the outer wall by conduction and convection.

In recent years, vacuum insulation materials having improved heat insulation performance have been used as compared with the conventional insulation materials described above. Vacuum insulation material can exhibit a heat insulation effect of up to ten times as much as a general insulation material by using micro porous inorganic fiber as an inner core material, surrounding the inner core material with a covering material and forming a vacuum inside the casing material.

If a small hole is generated during vacuum insulation, it is impossible to maintain the vacuum inside the envelope and the performance of the insulation can not be exhibited properly.

Therefore, special attention should be paid to the vacuum insulation. Nevertheless, there are a lot of sharp tools that can break vacuum insulation materials or fine protrusions formed on the outer wall in actual construction site.

In addition, the vacuum insulator may be damaged due to carelessness even during fastening of the fastener for securing the vacuum insulator.

However, there is a problem that the vacuum insulation material can not be visually recognized immediately after the breakage, and it is difficult to repair the breakage site because the problem is revealed after the construction.

In addition, there is a problem in that the heat insulation performance of the contact portion of the jacket material to which the vacuum insulation materials are connected is weak. That is, there is a problem that discontinuous linear thermal bridging occurs at the place where the heat insulating material and the edge of the heat insulating material meet.

KR 10-2012-0129385 A KR 10-1243695 B1

SUMMARY OF THE INVENTION An object of the present invention is to provide a double vacuum heat insulating block which can maintain the heat insulating performance in a rear-end vacuum insulating material even if the vacuum insulating material at the front end is broken by forming double vacuum insulating materials and arranging them so as to overlap with each other.

It is another object of the present invention to provide a double vacuum insulation block for preventing the deterioration of the heat insulating performance due to the connection part by arranging the vacuum insulation materials so that the vacuum insulation materials overlap each other.

Further, it is an object of the present invention to provide a vacuum insulator, which can be positioned in such a manner that when the heat insulating block is fixed to a wall of a building, And to provide a double vacuum insulated block with improved workability because the heat insulating block can be fastened to the wall at a high speed.

A first vacuum insulation material (100) having a first core (110), a first encapsulant (120) surrounding the first core (110) and sealing the inside of the first core (110) to maintain a vacuum state; A second vacuum insulation member 200 having a second core member 210 and a second casing member 220 surrounding the second core member 210 to seal the inside of the second core member 210 in a vacuum state; A first body 310 having a first insertion groove 312 through which the first vacuum insulation material 100 is inserted and a first vacuum insulation material 100 inserted into the first insertion groove 312; A second inserting groove 322 in which the second vacuum insulator 200 is inserted is formed on the rear surface of the first body 310 so that the second insulator 200 A block body 300 having a second body 320 to which the first body 320 is inserted; A first cover 400 coupled to the first body 310 to close the front surface of the first body 310; And a second cover 500 coupled to the second body 320 to close the rear surface of the second body 320. The first cover 400 and the second cover 500 are respectively And the second body 320 is located on the outer side of the block body 300. The second body 320 has one of the upper and lower surfaces protruding from the upper surface or the lower surface of the first body 310, The second vacuum insulator 200 may be disposed to be offset from the first body 310 so as to protrude from the left or right side of the first body 310, And the first cover 400 is disposed on the front surface of the first body 310 at a position prior to the first insertion groove 312 A first cover groove 314 is formed on the rear surface of the second body 320 and a second cover groove 314 is formed on the rear surface of the second body 320 at a position before the second insertion groove 322 A second cover groove 324 to which the second cover 500 can be coupled is formed and the block body 300 is formed on the inner surface of the first body 310 where the first vacuum heat insulating material 100 is disposed. The fastener 20 is positioned between the second cover groove 324 into which the second cover 500 is inserted and the second cover groove 324 in which the second cover groove 324 is inserted with the fastener 20. [ And is not visible from the outside of the first cover 400.

The first vacuum insulator 100 and the second vacuum insulator 200 of the present invention are characterized in that any one of the four corners is overlapped with each other.

The first vacuum insulator 100 and the second vacuum insulator 200 may have a difference in vertical height between the first body 310 and the second body 320 and between the first body 310 and the second body 320, And the second body 320 are overlapped with each other by a difference in height between the left and right sides of the second body 320.

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The first body 310 of the present invention is formed with a first display portion 316 for determining the position and shape of the second vacuum insulating material 200 on the bottom surface of the first insertion groove 312 And a second display portion 326 is formed on the second body 320 so as to measure the position and the shape of the first vacuum insulating material 100 on the bottom surface of the second insertion groove 322 .

The first body 310 of the present invention may have a first partition wall 318 which extends laterally across the first insertion groove 312 to define the first insertion groove 312, The second body 320 is formed with a second partition 328 which laterally traverses the second insertion groove 322 to define the second insertion groove 322.

The first vacuum insulator 100 of the present invention is divided into two parts so as to be respectively inserted into the first insertion grooves 312 defined by the first partition 318, (200) are formed in two parts so as to be respectively inserted into the second insertion groove (322) partitioned by the second partition (328).

The second body 320 in which the second vacuum heat insulating material 200 is inserted is disposed in a state of being staggered in the vertical direction and the left and right direction with respect to the first body 310 into which the first vacuum insulating material 100 is inserted, The first vacuum insulator 100 and the second vacuum insulator 200 are overlapped with each other in a certain region so that any one of the first vacuum insulator 100 or the second vacuum insulator 200 is damaged It is possible to maintain the adiabatic performance as it is.

In the present invention, when the plurality of block bodies 300 are connected, the first vacuum insulator 100 and the second vacuum insulator 200 are arranged in a double layer, It has an effect of preventing the occurrence of heat bridge.

The position and shape of the second vacuum insulating material 200 inserted into the second insertion groove 322 of the second body 320 may be formed on the bottom of the first insertion groove 312 of the first body 310, And a first display portion 316 which can be inserted into the first insertion groove 312 of the first body 310 is formed at the bottom of the second insertion groove 322 of the second body 320, The second display portion 326 can be formed to measure the position and the shape of the vacuum insulating material 100 so that the fastener 20 is fixed to the outer wall 10 when the block body 300 is fixed to the first vacuum insulating material 100, The second vacuum insulator 100 and the second vacuum insulator 200 can be prevented from being damaged during installation of the heat insulator.

The fastener 20 is attached to the outer wall 10 in a state in which the position and the shape of the first vacuum insulator 100 and the second vacuum insulator 200 are measured through the first display portion 316 and the second display portion 326, Since the block body 300 can be quickly fixed, the workability can be improved.

On the other hand, since the first vacuum insulator 100 and the second vacuum insulator 200 are stacked in layers, a small vacuum insulator whose manufacturing process is simple can be used, so that the unit price of the heat insulator can be reduced.

1 is a perspective view of a double vacuum insulation block according to a first embodiment of the present invention;
2 is a front triangular perspective view illustrating the disassembly of the dual vacuum insulation block according to the first embodiment of the present invention;
3 is a rear triangular perspective view illustrating the disassembly of the dual vacuum insulation block according to the first embodiment of the present invention.
4 is a front view of a dual vacuum insulation block according to a first embodiment of the present invention;
5 is a cross-sectional view taken along line A-A 'of FIG. 4;
6 is a plan view showing a process of installing the double vacuum insulation block on the outer wall 10 according to the first embodiment of the present invention.
Fig. 7 is a front view showing Fig. 6 (b). Fig.
8 is a front triangular perspective view illustrating the disassembly of a dual vacuum insulation block according to a second embodiment of the present invention;
9 is a front triangular perspective view illustrating the disassembly of the dual vacuum insulation block according to the second embodiment of the present invention.
10 is a front view showing a process in which the double vacuum insulation block according to the second embodiment of the present invention is installed on the outer wall 10. FIG.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention.

FIG. 1 is a perspective view of a double vacuum insulating block according to a first embodiment of the present invention, FIG. 2 is a front triangular perspective view showing decomposition of a double vacuum insulating block according to a first embodiment of the present invention, and FIG. 3 is a rear triangular perspective view showing the disassembly of the double vacuum insulation block according to the first embodiment.

1 to 3, a dual vacuum insulation block according to a first embodiment of the present invention includes a first vacuum insulation panel 100, a second vacuum insulation panel 200, a first vacuum insulation panel 100, And a second insertion groove 322 formed on the rear surface of the first body 310 and into which the second vacuum insulation member 200 is inserted are formed in the first body 310. The first body 310 has a first insertion groove 312 in which the second vacuum insulation member 200 is inserted, A first cover 400 closing a front surface of the first body 310 and a second cover closing a rear surface of the second body 320. The second body 320 includes a block body 300, 500).

Here, the second body 320 and the first body 310 are staggered from each other, and the second vacuum insulator 200 and the first vacuum insulator 100 are also arranged to be staggered to be overlapped with each other.

The first vacuum insulator 100 includes a first core 110 serving as a solid material for retaining the shape of the first vacuum insulator 100 and an outer periphery of the first core 110 And a first outer covering member 120 for sealing the inside of the envelope so as to maintain a vacuum state.

As the first core member 110, fumed silica, glass wool, urethane foam, or the like is used. As the first cover material 120, a multilayer film or a laminate film material coated with aluminum is used.

The first core member 110 is wrapped by the first casing member 120 and heat sealing is performed on the overlapping portion so that air inside the first core member 110 is drained to maintain the inside of the first casing member 120 in a vacuum state Seal it.

The second vacuum insulator 200 is also provided with a second core member 210 serving as a solid material for retaining the shape of the second vacuum insulator 200. The outer periphery of the second core member 210 And a second envelope material 220 sealing the inside of the envelope so as to maintain a vacuum state.

As the second core member 210, fumed silica, glass wool, urethane foam, or the like is used. As the second cover material 220, a multilayer film or a laminate film material coated with aluminum is used.

The second core member 210 is wrapped with the second casing member 220 and then the heat is sealed by heat sealing the overlapping portion so that the inside of the second casing member 220 is maintained in a vacuum state Seal it.

The block body 300 receives the first vacuum insulator 100 and the second vacuum insulator 200 and is fixed to the outer wall or the wall.

The block body 300 is formed with a first body 310 having a first insertion groove 312 formed in a shape corresponding to the first vacuum insulation panel 100 and a second vacuum insulation panel 200 A second body 320 is formed in which the second insertion groove 322 is formed in a corresponding shape.

The block body 300 is integrally formed with the second body 320 on the rear surface of the first body 310. Expanded Polystyrene (EPS), Extruded Polystyrene (XPS), Ethylene Vinyl Acetate (EVA), and Expanded Polypropylene (EPP) may be used as the material of the block body 300.

The first vacuum insulator 100 is inserted into the first insertion groove 312 of the first body 310. A first cover groove 314 is formed in the first body 310 at a position prior to the first insertion groove 312. A first cover 400, which will be described later, is inserted into the first cover groove 314 to close the front surface of the first body 310. The first cover 400 prevents the first vacuum insulator 100 inserted into the first insertion recess 312 from being pulled out.

The first cover groove 314 is formed first when the first body 310 is viewed from the front and the first insertion groove 312 is formed at the rear side of the first cover groove 314. [

The second vacuum insulator 200 is inserted into the second insertion groove 322 of the second body 320. The second cover groove 324 is formed at a position before the second insertion groove 322 of the second body 320. A second cover 500 to be described later is inserted into the second cover groove 324 to close the rear surface of the second body 320. The second cover 500 prevents the second vacuum heat insulator 200 inserted into the second insertion recess 322 from being pulled out.

The second cover groove 324 is formed first when the second body 320 is viewed from the rear side and the second insertion groove 322 is formed on the rear side of the second cover groove 324. [

The first cover 400 prevents the first vacuum insulator 100 inserted in the first insertion groove 312 from being pulled out and is inserted into the first cover groove 314 to close the front surface of the first body 310. [ It does. The first cover 400 is coupled to the first cover groove 314 in an interference fit manner or is attached using an adhesive or the like.

The second cover 500 prevents the second vacuum insulating material 200 inserted in the second insertion groove 322 from being pulled out and is inserted into the second cover groove 324 to close the back surface of the second body 320. [ It does. The second cover 500 is coupled to the second cover groove 314 in an interference fit manner or is attached using an adhesive or the like.

The materials of the first cover 400 and the second cover 500 are formed of the same material as the block body 300.

4 is a front view of a double vacuum insulation block according to a first embodiment of the present invention.

The second body 320 is formed so that the upper surface of the second body 320 protrudes upward from the upper surface of the first body 310 and the right side of the first body 310 protrudes further to the right than the right surface of the first body 310, As shown in FIG.

The lower surface of the second body 320 may protrude further downward than the lower surface of the first body 310 and the left surface may protrude further to the left than the left surface of the first body 310.

As the second body 320 and the first body 310 are staggered from each other, the second vacuum insulating material 200 is disposed to be offset from the first vacuum insulating material 100. Thus, the first vacuum insulator 100 and the second vacuum insulator 200 overlap each other in a certain region.

At this time, the upper right corner of the first vacuum insulation panel 100 and the lower left corner of the second vacuum insulation panel 200 overlap each other in the first vacuum insulation panel 100 and the second vacuum insulation panel 200. The first vacuum insulator 100 and the second vacuum insulator 200 are overlapped with each other at one of four corners depending on the positions of the first body 310 and the second body 320.

Further, the first body 310 and the second body 320 are vertically overlapped with each other by a difference d1 in the up-down direction and the left and right sides are diagonally overlapped with each other in the left-right direction. The upper and lower and left and right side elevation differences d1 and d2 are set so as to be able to block the linear heating bridge.

6, when the plurality of block bodies 300 are installed on the outer wall 10, the block body 300 and the first and second vacuum heat insulating materials 100 and 200 are overlapped with each other. It is possible to block the linear thermal bridging through the connecting portion between the block bodies 300.

In addition, since the first vacuum insulator 100 and the second vacuum insulator 200 are doubly overlapped, even if one of the two is broken during the installation, the heat insulating performance can be maintained through the other.

5 is a cross-sectional view taken along the line A-A 'in FIG.

The first body 310 is positioned in front of the block body 300 and the first insertion groove 312 and the first cover groove 314 are formed in the first body 310. The first vacuum insulator 100 is inserted into the first insertion groove 312 and the first cover 400 is inserted into the first cover groove 314 to close the front surface of the first body 310.

And the second body 320 is located behind the block body 300. At this time, the first body 310 and the second body 320 are integrally formed. A second insertion groove 322 and a second cover groove 324 are formed in the second body 320, respectively. A second vacuum insulator 200 is inserted into the second insertion groove 322 and a second cover 500 is inserted into the second cover groove 324 to close the rear surface of the second body 320.

The first vacuum insulator 100 and the second vacuum insulator 200 are staggered to occupy a partial area of each other. So you can double the heat escaping through the exterior walls of the building.

6 is a plan view showing a process of installing the double vacuum insulation block on the outer wall 10 according to the first embodiment of the present invention.

(a) In the initial block body 300, the first insertion groove 312, the first cover groove 314, the second insertion groove 322, and the second cover groove 324 are both opened .

(b) The second vacuum insulator 200 is inserted into the second insertion groove 322, and the second cover 500 is inserted into the second cover groove 324. Then, the block body 300 is brought into close contact with the outer wall 10 of the building to be installed. The plurality of fasteners 20 are put in a state in which the block body 300 is closely contacted. The block body 300 is firmly fixed to the outer wall 10 through the plurality of fasteners 20.

The plurality of fasteners 20 may be formed on the outer surface of the outer surface of the first inserting groove 312 so as to avoid the second insulator 200 on the bottom surface of the first inserting groove 312 in a state in which the first inserting groove 312 and the first cover groove 314 are opened. (10).

At this time, the second vacuum insulating material 200 is removed from the bottom surface of the first insertion groove 312 while avoiding the second vacuum insulating material 200 in a state where the first insertion groove 312 and the first cover groove 314 are opened. The fastener 20 is inserted into the second insertion groove 322 and the second insertion groove 322 and inserted into the outer wall 10 so that the fastener can avoid the second vacuum insulation material 200, (200) and the second vacuum insulator (200).

the first vacuum insulator 100 is inserted into the first insertion groove 312 and the first cover 400 is inserted into the first cover groove 314 to close the front surface of the first body 310, do. The fastener 20 starts from the bottom surface (bottom surface) of the first insertion groove 312 and passes through the space between the second cover groove 324 and the second cover groove 324 and is fixed to the outer wall. ), It is not visible from the outside.

The first vacuum insulator 100 is first inserted into the first insertion groove 312 and the block body 300 is brought into close contact with the outer wall 10 so that the second insulator 100 is inserted into the second insertion groove 322 2 vacuum insulator 200 may be inserted.

Fig. 7 is a front view showing Fig. 6 (b).

The first inserting groove 312 and the first cover groove 314 of the first body 310 are opened so that the position and shape of the second vacuum insulator 200 are formed on the bottom surface of the first inserting groove 312 The first display portion 316 is formed so that it can be measured.

The first display portion 316 is displayed on the bottom surface of the first insertion groove 312 so that the position and the shape of the second vacuum insulator 200 inserted into the second body 320 can be determined. The first display portion 316 may be highlighted on the bottom surface of the first insertion groove 312 with different colors.

The first display portion 316 allows the user to easily recognize the area of the second vacuum insulating material 200. When the block body 300 is fixed to the outer wall 10 by the fastener 20 through the first display portion 316, the fastener 20 can be stuck on the outer wall 10 by avoiding the second vacuum insulator 200. [ have. It is possible to prevent breakage of the second vacuum insulator 200 by the fastener 20 when the block body 300 is fixed to the outer wall 10. [

The second display portion 326 shown in FIG. 3 serves to measure the position of the first vacuum insulator 100 and has the same function as the first display portion 316. The detailed description thereof is replaced with a description of the second display portion 326. [

Generally, when a heat insulating material such as the first vacuum insulating material 100 and the second vacuum insulating material 200 is manufactured, if the thickness of the heat insulating material is large, the vacuum process takes a long time and the risk of vacuum breakage is high. Therefore, The cost increases.

In the present invention, a vacuum insulator having a small thickness of about 10 cm can be inserted into the block body 300 by using the first vacuum insulator 100 and the second vacuum insulator 200 in a double layer.

That is, since the vacuum insulator having a small thickness can be used, the manufacturing cost of the vacuum insulator used in the heat insulating block can be reduced, and the cost of the heat insulator block can be reduced by using the vacuum insulator having a low unit cost.

FIG. 8 is a front perspective triangulation perspective view showing the disassembly of the double vacuum insulation block according to the second embodiment of the present invention, and FIG. 9 is a front perspective triangulation perspective view showing the decomposition of the double vacuum insulation block according to the second embodiment of the present invention .

8 and 9, the double vacuum insulation block according to the second embodiment of the present invention includes a first vacuum insulation panel 100, a second vacuum insulation panel 200, a first vacuum insulation panel 100, A first body 310 having a first partition 310 and a first partition 318 defining a first insertion groove 312 and a first insertion groove 312 to be inserted into the first body 310; A block body 300 having a second body 320 formed with a second partition 328 for partitioning a second insertion groove 322 into which the heat insulating material 200 is inserted and a second insertion groove 322, 1 includes a first cover 400 for closing the front surface of the body 310 and a second cover 500 for closing the rear surface of the second body 320.

Here, the second body 320 and the first body 310 are staggered from each other, and the second vacuum insulator 200 and the first vacuum insulator 100 are also arranged to be staggered to be overlapped with each other.

The first vacuum insulator 100 is divided into two portions so as to be respectively inserted into the first insertion grooves 312 defined by the first partition 318 and the second vacuum insulator 200 is divided into two portions, In the second insertion groove 322 partitioned by the second insertion groove 322. [

The second embodiment differs from the first embodiment in that the first partition 318 separating the first insertion groove 312 in two parts transversely across the first insertion groove 312 and the second insertion groove 322, A second partition 328 is formed to horizontally partition the second insertion groove 322 into two parts. The second embodiment includes the first embodiment, and a description of overlapping configurations is omitted.

The first partition 318 is formed to protrude laterally across the longitudinal center of the first insertion groove 312 of the first body 310 and divides the first insertion groove 312 into two portions.

The second partition 328 is formed to protrude laterally across the longitudinal center of the second insertion groove 322 of the second body 320 and divides the second insertion groove 322 into two parts.

At this time, the positions of the first partition 318 and the second partition 328 may be changed according to the sizes of the first vacuum insulator 100 and the second vacuum insulator 200.

The first vacuum insulator 100 inserted into the first insertion groove 312 is also divided into two parts. The first vacuum insulator 100 divided into two parts is inserted into the first insertion groove 312 partitioned by the first partition wall 318, respectively.

The second vacuum insulator 200 inserted into the second insertion groove 322 is also divided into two parts. Each of the second vacuum insulators 200 divided into two parts is inserted into the second insertion groove 322 partitioned by the second partition wall 328, respectively.

Meanwhile, as the second insertion groove 322 is divided into two parts by the second partition 328, the first display part 316 is also divided into two parts. The position and shape of the second vacuum insulator 200 can be determined through the first display portion 316 and the position and shape of the second partition 328 can be determined.

In addition, as the first insertion groove 312 is divided into two parts by the first partition 318, the second display part 326 is also divided into two parts. The position and shape of the first vacuum insulator 100 can be determined through the second display portion 326 and the position and shape of the first partition 318 can be determined.

10 is a front view showing a process in which the double vacuum insulation block according to the second embodiment of the present invention is installed on the outer wall 10. FIG.

10 shows a state in which a plurality of fasteners 20 are removed from the bottom surface of the first insertion groove 312 while avoiding the second vacuum insulation material 200 in a state in which the first insertion groove 312 and the first cover groove 314 are opened. To the outer wall (10).

The first vacuum insulator 100 and the second vacuum insulator 200 may be manufactured to have a large size of 1 to 2 m. Since the size of the first vacuum insulator 100 and the second vacuum insulator 200 is large, the block body 300 is more firmly fixed to the outer wall 10 of the building You need to fix it.

For this purpose, in the second embodiment, the first partition 318 and the second partition 328, which transverse the first insertion groove 312 and the second insertion groove 322, respectively, are formed, The block body 300 can be more firmly fixed to the outer wall 10 of the building by allowing the fastener 20 to be inserted into the first and second partition walls 318 and 328.

Referring to the first display portion 316 and the second display portion 326, the fastener 20 is pushed to a position where the first vacuum insulator 100 and the second vacuum insulator 200 are not broken, Can be easily fixed to the outer wall 10 of the building.

The block body 300 can be more firmly fixed to the outer wall 10 by vertically and horizontally pushing the fastener 20.

10: outer wall 20: fastener
100: first vacuum insulator
110: first core member 120: first shell member
200: second vacuum insulator
210: second core member 220: second casing member
300: block body
310: first body
312: first insertion groove 314: first cover groove 316: first display portion
318: first partition
320: second body
322: second insertion groove 324: second cover groove 326: second display portion
328: second partition
400: first cover
500: second cover

Claims (7)

A first vacuum insulation material (100) having a first core member (110), and a first shell member (120) surrounding the first core member (110) and sealing the inside of the first core member (110) to maintain a vacuum state.
A second vacuum insulation member 200 having a second core member 210 and a second casing member 220 surrounding the second core member 210 to seal the inside of the second core member 210 in a vacuum state;
A first body 310 having a first insertion groove 312 through which the first vacuum insulation material 100 is inserted and a first vacuum insulation material 100 inserted into the first insertion groove 312; A second inserting groove 322 in which the second vacuum insulator 200 is inserted is formed on the rear surface of the first body 310 so that the second insulator 200 A block body 300 having a second body 320 to which the first body 320 is inserted;
A first cover 400 coupled to the first body 310 to close the front surface of the first body 310; And a second cover 500 coupled to the second body 320 to close the rear surface of the second body 320,
The first cover 400 and the second cover 500 are positioned on opposite sides of the block body 300,
One of the upper and lower surfaces of the second body 320 protrudes from the upper surface or the lower surface of the first body 310 and one of the left and right sides protrudes from the left or right side of the first body 310 The first body 310 and the second body 310,
The second vacuum insulator 200 is disposed to be staggered with respect to the first vacuum insulator 100 and overlapped with the first vacuum insulator 100,
A first cover groove 314 is formed on the front surface of the first body 310 so that the first cover 400 can be engaged with the first insertion groove 312,
A second cover groove 324 is formed on the rear surface of the second body 320 so that the second cover 500 can be engaged with the second insertion groove 322,
A fastener 20 for fixing the block body 300 to the outer wall 10 is disposed on an inner surface of the first body 310 where the first vacuum insulator 100 is disposed, Is not visible from the outside of the first cover (400) through the second cover groove (324) into which the second cover (500) is inserted and the second cover groove (324) continuing.
The method according to claim 1,
Wherein the first vacuum insulator (100) and the second vacuum insulator (200) are arranged so that any one of the four corners is overlapped with each other.
The method according to claim 1,
The first vacuum insulator 100 and the second vacuum insulator 200 may be disposed on both sides of the first body 310 and the second body 320, (320) by a difference in height between the left and right sides of the double-layered vacuum insulation block (320).
delete The method according to claim 1,
In the first body 310,
A first display portion 316 is formed on the bottom surface of the first insertion groove 312 to allow the user to gauge the position and shape of the second vacuum insulator 200,
In the second body 320,
Wherein a second display portion (326) is formed on a bottom surface of the second insertion groove (322) so as to measure a position and a shape of the first vacuum insulation material (100).
The method according to claim 1,
In the first body 310,
A first partition wall 318 is formed across the first insertion groove 312 to define the first insertion groove 312,
In the second body 320,
And a second partition wall (328) is formed to transverse the second insertion groove (322) to define the second insertion groove (322).
The method according to claim 6,
The first vacuum insulation material (100)
And are formed in two parts so as to be respectively inserted into the first insertion grooves 312 defined by the first partition 318,
The second vacuum insulation material (200)
(322) divided by the second partition wall (328). The double vacuum insulation block according to claim 1, wherein the second partition wall (328) is formed in two parts.

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