KR20230105918A - Vacuum insulation material assembly with tilting and thermal bridge protecting function - Google Patents

Abstract

The present invention includes a housing having both ends penetrating, including a first piece disposed on the outdoor side and a second piece disposed on the indoor side and parallel to the first piece, and having a vacuum insulation material disposed between the first and second pieces; A first engagement that interconnects one edge of the first and second pieces to surround the vacuum insulation material and allows engagement and tilting of one of the plurality of housings (hereinafter referred to as a first housing) and an adjacent housing (hereinafter referred to as a second housing) A second engagement means for interconnecting the other edge of the first and second pieces to surround the vacuum insulation material and allowing engagement and tilting of the first housing and the adjacent housing (hereinafter referred to as the third housing) separately from the second housing. Tilting coupling part comprising a; and a first blocking cutout formed to divide the first engaging means and a second blocking cutout formed to divide the second engaging means to prevent thermal bridge between the outdoor side and the inside. It relates to a vacuum insulation assembly having a tilting and thermal bridge prevention function, characterized in that it includes a thermal bridge prevention unit.

Description

Vacuum insulation assembly with tilting and thermal bridge prevention function {VACUUM INSULATION MATERIAL ASSEMBLY WITH TILTING AND THERMAL BRIDGE PROTECTING FUNCTION}

The present invention relates to a vacuum insulation assembly having tilting and thermal bridge prevention functions, and more particularly, it can be assembled according to the shape of the surface to be installed and used as an external finishing material by itself, as well as heat inflow of indoor and outdoor sides. It relates to a vacuum insulation assembly having a tilting and thermal bridge prevention function capable of fundamentally blocking overflow.

Insulation materials are applied to modern buildings to save energy through thermal insulation and insulation performance improvement, and among these insulation materials, conventional insulation materials such as Styrofoam or urethane foam require thick insulation materials to comply with building construction regulations and are very vulnerable to fire. There are downsides.

In view of the above, in recent years, vacuum insulation materials have been in the limelight as insulation materials for buildings.

A vacuum insulator is an insulator in which an organic core material such as polyurethane foam or an inorganic core material such as glass fiber or silica is inserted into an outer shell material and then sealed by depressurizing the inside.

Vacuum insulation materials have recently attracted great attention as insulation materials or sound insulation materials for buildings because they have excellent insulation performance or sound insulation performance because there is no or very little air serving as a medium for transmitting heat or sound.

However, unlike conventional insulation materials, the vacuum insulation material maintains its insulation and sound insulation properties only when the outer shell maintains airtightness and the inside is kept in a vacuum state. However, special care is required during installation.

Therefore, when constructing the vacuum insulation material, it is difficult to use fasteners such as nails or anchor bolts, and there are disadvantages in that construction or installation takes a lot of time.

In view of the above, the same may be mentioned as "a vacuum insulation installation bracket with detachable fixing part" (hereinafter referred to as prior art) of Registered Patent No. 10-2222938 filed and registered by the present applicant.

As shown in FIG. 8, the prior art is used to mount the vacuum insulator 10 while being fixed to a wall surface on which the vacuum insulator 10 is to be installed.

The bracket is fixed to the wall surface by passing an anchor bolt or the like through the bracket fastening hole 150 formed in the base frame 100.

After fixing the bracket to the wall surface, one side of the vacuum insulation material 10 is inserted between the base frame 100 and the fixing frame 130 of the bracket.

Then, another bracket is installed on the other side of the vacuum insulator 10 in the same way so that both sides of the vacuum insulator 10 are fixed by the bracket.

At this time, the bracket fixing the other side of the vacuum insulator 10 is formed on the bracket because it is easy to mount on the wall after inserting the vacuum insulator 10 between the base frame 100 and the fixing frame 130. The bracket fastening hole 150 is coupled so that the vacuum insulator 10 is directed outward.

This is because when the bracket fastening hole 150 is directed toward the vacuum insulator 10, the bracket fastening hole 150 is covered by the vacuum insulator 10, making it inconvenient to fasten with an anchor bolt or the like.

However, the prior art has a problem in that cumbersome operations such as installing the vacuum insulation material 10 on the wall and then installing the lumber again, and additionally installing a separate external finishing material 30 on the installed lumber.

In addition, in the prior art, in fixing and installing a plurality of vacuum insulators 10 along a wall, a cumbersome task of installing brackets including a plurality of base frames 100 at each edge of the vacuum insulator 10 is involved. There were also problems.

The present invention was invented to improve the above problems, and can be assembled according to the shape of the surface to be installed and used as an external finishing material by itself, as well as fundamentally blocking heat inflow and outflow between indoor and outdoor sides. It is to provide a vacuum insulation assembly having a tilting and thermal bridge prevention function.

In order to achieve the above object, the present invention includes a first piece disposed on an outdoor side and a second piece disposed indoors and parallel to the first piece, wherein the first piece and the second piece are disposed indoors. A housing with both ends penetrating in which a vacuum insulation material is disposed therebetween; One edge of the first piece and the second piece are interconnected to surround the vacuum insulation material and allow engagement and tilting of one of the plurality of housings (hereinafter referred to as the first housing) and an adjacent housing (hereinafter referred to as the second housing) A first engaging means for connecting the first piece and the other side edge of the second piece to each other to surround the vacuum insulation material and engage the first housing and the neighboring housing (hereinafter referred to as the third housing) separately from the second housing. and a tilting coupling part including a second engaging means allowing tilting; and a first blocking cutout formed to divide the first engaging means and a second blocking cutout formed to divide the second engaging means to prevent thermal bridge between the outdoor side and the inside. It will be possible to provide a vacuum insulator assembly having a tilting and thermal bridge preventing function, characterized in that it includes a thermal bridge preventing part including a cutout part.

Here, the first engaging means is bent and extended from one edge of the first piece, and is formed convexly in a direction away from a first imaginary plane connecting the first piece and one edge of the second piece to each other. a protruding curved surface and a first combining recessed curved surface that is bent and extended from one edge of the second piece, is convexly formed in a direction approaching the first imaginary plane, and is connected to the first combined protruding curved surface; The blocking cutout is formed on the first engaging protruding curved surface or the first engaging depressed curved surface, or is formed at a joint between the first engaging protruding curved surface and the first engaging depressed curved surface, and is formed in the first engagement means of the first housing. is connected to the second engaging means of the second housing.

At this time, the second engaging means is bent and extended from the other edge of the first piece, and is convexly formed in a direction approaching a second imaginary plane connecting the first piece and the other edge of the second piece to each other. a coupling depression curved surface, and a second coupling protrusion curved surface bent and extended from the other edge of the second piece, convexly formed in a direction away from the second imaginary plane, and connected to the second coupling recessed curved surface; The blocking cutout is formed on the second engaging depressed curved surface or the second engaging protruding curved surface, or is formed at a junction between the second engaging depressed curved surface and the second engaging protruding curved surface, and the second engaging means of the first housing. is connected to the first engaging means of the third housing.

The thermal bridge prevention unit is made of a material having a lower thermal conductivity than that of the first housing, and includes a first closing piece closing the open end surface of the first housing, and a first closing piece extending from the first closing piece to the first housing. A first fitting protrusion piece integrally formed with the first closing piece, which protrudes to correspond to the shape of the inner edge of the open end surface and is fitted into the inside of the first end portion of the first housing, and the first closing piece It protrudes from the piece and is formed to extend from both sides of the first fitting protruding piece, respectively, and is disposed at one end of each of the first blocking cutout and the second blocking cutout, and the first closing piece and the first fitting A first spacer formed integrally with the protruding piece, a second closing piece made of a material having a lower thermal conductivity than the first housing, and closing the open other end surface of the first housing, and A second fitting protrusion piece formed integrally with the second closing piece, which protrudes to correspond to the shape of the inner edge of the open other end surface of the first housing and is fitted to the inside of the other end of the first housing; , Protruding from the second closing piece and extending from both sides of the second fitting protruding piece at the same time, disposed at the other end of each of the first blocking cutout and the second blocking cutout, the second closing piece And a second spacer integrally formed with the second fitting protrusion piece, passing through a plurality along the inner side of the edge of the first closing piece and disposed outside the first fitting protrusion piece, the first closing piece being disposed outside the first fitting protrusion piece. A first fastening hole through which a fastener for fixing one end of the housing passes, and a plurality of holes along the inside of the edge of the second closing piece are disposed outside the second fitting protruding piece, and the second closing piece is disposed on the outside of the second fitting protruding piece. 1 at a position corresponding to a second fastening hole through which a fastener fixed to the other end of the housing passes, and a plurality of first fastening holes and a plurality of second fastening holes along the inner surface of the first housing, respectively. An internal fastening rib formed integrally with the first housing, having a connection hole at the center of which is disposed in a straight line with the centers of the first fastening hole and the second fastening hole, and in which a plurality of the fasteners are respectively fixed to the connection hole. It is characterized in that it further comprises.

In addition, the thermal bridge prevention unit includes a plurality of first auxiliary fastening ribs extending along the outer edge of the first closing piece, and a first auxiliary fastening hole through which the fastener is inserted through each of the first auxiliary fastening ribs, , Second auxiliary fastening ribs extending in plurality along the outer edge of the second closing piece, second auxiliary fastening holes through each of the second auxiliary fastening ribs through which the fasteners are inserted, and of the first housing It is integrally formed with the first housing at a position corresponding to each of the plurality of first auxiliary fastening holes and the plurality of second auxiliary fastening holes along the outer surface, and the first auxiliary fastening hole and the second auxiliary fastening hole It is characterized in that it further includes an auxiliary connection hole disposed in a straight line with the center at the center and an external fastening rib to which the plurality of fasteners are respectively fixed to the auxiliary connection hole.

In addition, a first bracket extending along the connection portion where the second piece and the first engaging means meet and supporting the second piece of the second housing, along the connection portion where the first piece and the second engagement means meet. It is characterized in that it further comprises a second bracket extending and supporting the first piece of the third housing.

In addition, as constituting the first bracket, a first extension rib obliquely extending along a connection portion where the second piece and the first engaging means meet, and constituting the first bracket, the first extension rib A fixing rib extending parallel to the first piece and the second piece along the edge of the distal end and contacting an installation target surface facing the second piece, and configuring the first bracket, the distal end of the fixing rib A second extension rib extending obliquely along an edge and constituting the first bracket, extending parallel to the first piece and the second piece along the distal end edge of the second extension rib, the second housing A first support rib in contact with the second piece of and constituting the second bracket, extending along a connection portion where the first piece and the second engaging means meet, and contacting the first piece of the third housing. It is characterized in that it comprises a second support rib to.

According to the present invention having the configuration as described above, the following effects can be achieved.

First of all, the present invention can be installed by tilting and combining the housings according to the shape of the installation target surface, so it can be used as a heat insulating material for buildings with various structures and shapes, as well as being used as an external finishing material itself, so it is versatile It is very excellent from the side and will be able to fundamentally block the heat inflow and outflow of the indoor and outdoor sides.

The present invention divides the housing surrounding the vacuum insulator to further improve the insulation performance of the vacuum insulator by blocking heat inflow and outflow between the indoor and outdoor sides, that is, the thermal bridge phenomenon, and further reduce the cooling and heating load of the building. will be able to

In addition, the present invention separates the open ends of the housing, which is through both ends, with a closing piece and a spacer structure made of a material having lower thermal conductivity than the housing, so that the divided state of the divided housing can be maintained at regular intervals, thereby reducing the thermal bridge phenomenon. It will be able to help the realization of green energy buildings by promoting clear blocking.

In particular, the present invention has excellent versatility as it can be applied to vacuum insulators having various specifications by manufacturing various widths of the finishing pieces according to the thickness of the vacuum insulator embedded in the housing and assembling them in the housing.

In addition, since the present invention can easily install vacuum insulation materials as well as external finishing materials such as slabs or marble plates with respect to the wall, it will be possible to significantly improve the convenience of work.

In particular, the present invention has a structure in which installation brackets themselves are provided on both sides of each housing installed in a row parallel to the installation target surface, so that the operator can intuitively grasp and install and construct regardless of skill level It is a very effective invention in

Above all, the vacuum insulator assembly according to the present invention requires fixing one of the brackets on both sides of the housing in which the vacuum insulator is accommodated without making the mistake of inadvertently penetrating an anchor bolt or fixture into the housing in which the vacuum insulator is accommodated. , When the vacuum insulation is installed on the installation target surface including the wall, it has a feature that the problem of facing the damage and unusable state caused by the anchor or fastener penetrating the vacuum insulation can be prevented in advance.

In addition, the present invention can reduce work man-hours and install and install quickly and efficiently without the need for cumbersome additional work of existing vacuum insulation installation brackets, including the prior art, for example, additional fixed installation on walls or installation objects, efficiency can be greatly improved.

In addition, since the vacuum insulation assembly according to the present invention can be applied as an external finishing material itself, it has the advantage of minimizing the waste of unnecessary raw materials and shortening the construction time.

1 is a side conceptual view showing the overall coupling relationship of a vacuum insulation assembly having tilting and thermal bridge prevention functions according to an embodiment of the present invention.
2 is a conceptual view showing the structure of a first housing, which is a main part of a vacuum insulation assembly having tilting and thermal bridge prevention functions according to various embodiments of the present invention, as viewed from point A in FIG. 1;
3 is a conceptual view showing the coupling relationship of the first housing, which is a main part of the vacuum insulation assembly having tilting and thermal bridge prevention functions according to various embodiments of the present invention, as viewed from point A in FIG. 1;
Figure 4 shows the structure of the first and second closing pieces of the thermal bridge prevention unit, which is the main part of the vacuum insulation assembly having tilting and thermal bridge prevention functions according to various embodiments of the present invention, as viewed from viewpoints A and B in FIG. a concept
5 is a conceptual diagram sequentially showing a first closing piece, a first housing, and a second closing piece of a thermal bridge prevention unit, which is a main part of a vacuum insulation assembly having tilting and thermal bridge prevention functions according to another embodiment of the present invention.
6 is a conceptual diagram sequentially showing a first closing piece, a first housing, and a second closing piece of a thermal bridge prevention unit, which is a main part of a vacuum insulation assembly having tilting and thermal bridge prevention functions according to another embodiment of the present invention.
7 is a conceptual diagram showing a construction state of a vacuum insulation assembly having tilting and thermal bridge prevention functions according to various embodiments of the present invention;
8 is a side cross-sectional conceptual view showing the overall construction state of a conventional vacuum insulation installation bracket

Advantages and features of the present invention, and methods for achieving them, will become clear with reference to the embodiments described below in detail in conjunction with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below and will be implemented in various different forms.

In this specification, this embodiment is provided to complete the disclosure of the present invention, and to completely inform those skilled in the art of the scope of the invention to which the present invention belongs.

And the invention is only defined by the scope of the claims.

Thus, in some embodiments, well-known components, well-known operations and well-known techniques have not been described in detail in order to avoid obscuring the interpretation of the present invention.

In addition, like reference numerals designate like elements throughout the specification, and terms used (referred to) in this specification are for describing embodiments and are not intended to limit the present invention.

In this specification, the singular also includes the plural unless specifically stated in the phrase, and components and operations referred to as 'comprising (or including)' do not exclude the presence or addition of one or more other components and operations. .

Unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used in a meaning commonly understood by those of ordinary skill in the art to which the present invention belongs.

In addition, terms defined in commonly used dictionaries are not interpreted ideally or excessively unless they are defined.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

First, FIG. 1 is a conceptual side view showing the overall coupling relationship of a vacuum insulation assembly having tilting and thermal bridge prevention functions according to an embodiment of the present invention.

And, FIG. 2 is a conceptual view showing the structure of the first housing 100, which is a main part of the vacuum insulation assembly having tilting and thermal bridge prevention functions according to various embodiments of the present invention, as viewed from point A in FIG.

And, FIG. 3 is a conceptual view showing the coupling relationship of the first housing 100, which is a main part of the vacuum insulation assembly having tilting and thermal bridge prevention functions according to various embodiments of the present invention, as viewed from point A in FIG. 1. .

4 shows the first closing piece 710 and the second closing piece 720 of the thermal bridge prevention unit 700, which is a main part of the vacuum insulation assembly having tilting and thermal bridge prevention functions according to various embodiments of the present invention. It is a conceptual diagram showing the structure viewed from A and B viewpoints in FIG. 1 .

5 shows the first closing piece 710 of the thermal bridge prevention unit 700, which is the main part of the vacuum insulation assembly having tilting and thermal bridge prevention functions according to another embodiment of the present invention, and the first housing 100 , It is a conceptual diagram sequentially showing the second closing piece 720.

6 shows the first closing piece 710 of the thermal bridge prevention unit 700, which is a main part of the vacuum insulation assembly having tilting and thermal bridge prevention functions according to another embodiment of the present invention, and the first housing 100 And, it is a conceptual diagram sequentially showing the second closing piece 720.

In addition, FIG. 7 is a conceptual diagram illustrating a construction state of a vacuum insulation assembly having functions of tilting and preventing thermal bridge according to various embodiments of the present invention.

It can be seen that the present invention has a structure in which the housing 100 is provided with the tilt coupling part 400 and the thermal bridge prevention part 700 as shown in the drawing.

The housing 100 includes a first piece 101 disposed on the outdoor side and a second piece 102 disposed on the indoor side and parallel to the first piece 101, the first piece 101 and the second piece 102. It is a member through both ends in which the vacuum insulator 500 is disposed between the two pieces 102.

The tilting coupling part 400 includes a first engaging means 410 and a second engaging means 420 interconnecting the first and second pieces 101 and 102 .

The first engaging means 410 interconnects one side edge of the first piece 101 and the second piece 102 to surround the vacuum insulation material 500 and surrounds the vacuum insulation material 500 and covers one housing among a plurality of housings (hereinafter, the first housing 100). ) and the adjacent housing (hereinafter, the second housing 200) to allow engagement and tilting.

The second engagement means 420 interconnects the other edges of the first piece 101 and the second piece 102 to surround the vacuum insulator 500 and separates the second housing 200 from the first housing 100. It is to allow engagement and tilting of a housing (hereinafter referred to as the third housing 300) adjacent to the housing.

The thermal bridge prevention unit 700 includes a first blocking cutout 701 cut to divide the first engaging means 410 as shown in FIG. 3 in order to prevent thermal bridge between the outdoor side and the inside side, It includes a second blocking cutout 702 cut to divide the second engaging means 420 .

Of course, the present invention can be applied to the above embodiments and also to the following various embodiments.

First, the first engaging means 410, looking in more detail with reference to FIG. 2 together with FIG. will be able to apply

The first coupling protruding curved surface 411 is bent and extended from one edge of the first piece 101, and a first virtual plane 103 interconnecting one edge of the first piece 101 and the second piece 102. It is formed convexly in a direction away from .

The first coupling recessed curved surface 412 is bent and extended from one edge of the second piece 102, and is convexly formed in a direction closer to the first virtual plane 103 to be connected to the first coupling protruding curved surface 411 will be.

Here, the first blocking cutout 701 is formed on the first combining protruding curved surface 411 or the first combining depressed curved surface 412, or the first combining protruding curved surface 411 and the first combining depressed curved surface 412. It can be formed in the connection part of.

At this time, the first engaging means 410 of the first housing 100 may be connected to the second engaging means 420 of the second housing 200 (see FIG. 7 hereinafter).

On the other hand, the second engagement means 420, looking more specifically with reference to FIG. 2 together with FIG. 1, an embodiment of a structure including a second coupling recessed curved surface 421 and a first coupled protruding curved surface 422 will be able to apply

The second coupling recessed curved surface 421 is bent and extended from the other edge of the first piece 101, and a second imaginary plane 104 interconnecting the other edge of the first piece 101 and the second piece 102. It is formed convexly in the direction approaching to .

The second coupling protruding curved surface 422 is bent and extended from the other edge of the second piece 102, and is convexly formed in a direction away from the second imaginary plane 104 to be connected to the second coupling recessed curved surface 421. .

Here, the second blocking cutout 702 is formed on the second combined recessed curved surface 421 or the second combined protruding curved surface 422, or the second combined recessed curved surface 421 and the second combined protruding curved surface 422. It can be formed in the connection part of.

At this time, the second engaging means 420 of the first housing 100 may be connected to the first engaging means 410 of the third housing 300 (see FIG. 7 below).

Meanwhile, in the thermal bridge prevention unit 700, as shown in FIGS. 4(a) and 4(c), the first fitting protrusion 711 protrudes from the first closing piece 710, and the first fitting protrusion 711 protrudes. An embodiment of a structure in which the first spacer 712 extends from both sides of the protruding piece 711 may be applied.

The first closing piece 710 is made of a material having lower thermal conductivity than the first housing 100 and closes the open end surface of the first housing 100 .

The first fitting protruding piece 711 is protruded from the first closing piece 710 to correspond to the shape of the inner edge of the open end surface of the first housing 100, and is formed on the inside of one end of the first housing 100. To be fitted, it is formed integrally with the first closing piece 710.

The first spacer 712 protrudes from the first closing piece 710 and extends from both sides of the first fitting protruding piece 711, respectively, to form the first blocking cutout 701 and the second blocking cutout 702. ) to be disposed at one end of each, and integrally formed with the first closing piece 710 and the first fitting protruding piece 711.

In addition, in the thermal bridge prevention unit 700, as shown in FIGS. 4(b) and 4(d), the second fitting protrusion 721 protrudes from the second closing piece 720, and the second fitting An embodiment of a structure in which the second spacers 722 extend from both sides of the protruding piece 721 may be applied.

The second closing piece 720 is made of a material having lower thermal conductivity than the first housing 100 and closes the other open end surface of the first housing 100 .

The second fitting protrusion 721 protrudes from the second closing piece 720 to correspond to the shape of the inner edge of the open other end surface of the first housing 100, and is formed on the inside of the other end of the first housing 100. To be fitted, it is formed integrally with the second closing piece 720.

The second spacer 722 protrudes from the second closing piece 720 and extends from both sides of the second fitting protruding piece 721, respectively, to form the first blocking cutout 701 and the second blocking cutout 702. ) is disposed at the other end of each, and is integrally formed with the second closing piece 720 and the second fitting protruding piece 721.

Here, the first and second closing pieces 710 and 720 are manufactured with various distances between the corresponding parts of the first and second pieces 101 and 102 of the first and second closing pieces 710 and 720, that is, the upper and lower edges. By doing so, it is possible to finish both open end surfaces of the first housing 100 in which the vacuum insulators 500 having different thicknesses are accommodated, thereby increasing the degree of freedom in design and construction.

On the other hand, the thermal bridge prevention unit 700 penetrates in plurality along the inner side of the edge of the first closing piece 710 and is disposed outside the first fitting protruding piece 711, and the first closing piece 710 is placed on the outside of the first fitting protruding piece 711. A first fastening hole 713 through which a fastener (hereinafter not shown) fixed to one end of the housing 100 may be further provided.

In addition, the thermal bridge prevention unit 700 penetrates in plurality along the inner side of the edge of the second closing piece 720 and is disposed on the outside of the second fitting protruding piece 721, and the second closing piece 720 is placed on the outside of the first fitting protruding piece 721. A second fastening hole 723 through which a fastener fixed to the other end of the housing 100 may be further provided.

In addition, the thermal bridge prevention unit 700 is located along the inner surface of the first housing 100 at positions corresponding to the plurality of first fastening holes 713 and the plurality of second fastening holes 723, respectively, in the first housing ( 100) and is formed integrally with the first fastening hole 713 and the second fastening hole 723 and the center of the connection hole 151 disposed in a straight line, and a plurality of fastenings to the connection hole 151 Internal fastening ribs 150 to which the spheres are respectively fixed may be further provided.

Meanwhile, the thermal bridge prevention unit 700 may further include first auxiliary fastening ribs 714 extending in plurality along the outer edge of the first closing piece 710 as shown in FIGS. 5 and 6 .

In addition, the thermal bridge prevention unit 700 may further include first auxiliary fastening holes 715 through which the fasteners are inserted through each of the first auxiliary fastening ribs 714 .

In addition, the thermal bridge prevention unit 700 may further include second auxiliary fastening ribs 724 extending in plurality along the outer edge of the second closing piece 720 .

In addition, the thermal bridge prevention unit 700 may further include second auxiliary fastening holes 725 through each of the second auxiliary fastening ribs 724 through which fasteners are inserted.

In addition, the thermal bridge prevention unit 700 is located at a position corresponding to each of the plurality of first auxiliary fastening holes 715 and the plurality of second auxiliary fastening holes 725 along the outer surface of the first housing 100. It is integrally formed with the housing 100 and has an auxiliary connection hole 161 disposed in a straight line with the center of the first auxiliary fastening hole 715 and the second auxiliary fastening hole 725, and the auxiliary connection hole ( 161) may further include an external fastening rib 160 to which a plurality of fasteners are respectively fixed.

When the widths of the first piece 101 and the second piece 102 of the first housing 100 are formed long, each of the first closing piece 710 and the second closing piece 720 is the first piece 101 A problem such as a lifting phenomenon or a confidentiality release may occur in a portion in contact with the edge of the second piece 102 .

The above-mentioned first auxiliary fastening rib 714 and the second auxiliary fastening rib 724 and the above-mentioned external fastening rib 160 have a first piece 101 and a second piece 102 formed long in width. 1 In the housing 100, the first closure piece 710 and the second closure piece 720 each come into contact with each other along the edges of the first piece 101 and the second piece 102. It can be said that it is a technical means prepared to prevent the occurrence of such problems in advance.

On the other hand, the present invention, looking more specifically with reference to FIGS. 5 and 6 together with FIG. 2 , by further comprising the first and second brackets 110 and 120, the first housing 100 and adjacent to the second, The engagement construction of the 3 housings 200 and 300 is possible as shown in FIG. 7 .

That is, the first bracket 110 extends along the connection portion where the second piece 102 and the first engaging means 410, specifically, the first coupling recessed curved surface 412 meet, and the second housing 200 The two pieces 202 are supported, or the second engagement means 420 of the second housing 200 is tilted and coupled as shown in FIG. 7 .

The second bracket 120 extends along a connection portion where the first piece 101 and the second engaging means 420, specifically, the second coupling recessed curved surface 421 meet, and the first piece of the third housing 300. It is provided to support the 301 or support the first engaging means 410 of the third housing 300 to be tilted and coupled as shown.

Therefore, the vacuum insulation assembly according to the present invention, as shown in FIG. 7 , the first engaging means 410 of the first housing 100 and the second engaging means of the second housing 200 based on the first housing 100 At the same time as the 420 faces or engages, the second engaging means 420 of the first housing 100 and the first engaging means 410 of the third housing 300 face each other or engage in a pattern repeatedly formed. You will be able to.

Meanwhile, the first bracket 110 includes a first extension rib 111, a fixing rib 112, a second extension rib 113, and a first support rib 114 as shown in FIGS. 2, 5, and 6 An embodiment of the structure may be applied.

First, the first extension rib 111 obliquely extends along the connection portion where the second piece 102 and the first engaging means 410 meet.

In addition, the fixing rib 112 extends parallel to the first piece 101 and the second piece 102 along the distal edge of the first extension rib 111, and is installed facing the second piece 102. It is to contact a surface (not shown below).

And, the second extension rib 113 obliquely extends along the edge of the distal end of the fixing rib 112 .

Also, the first support rib 114 extends parallel to the first piece 101 and the second piece 102 along the distal end edge of the second extension rib 113, and the second piece of the second housing 200 It is in contact with the piece 202.

In addition, the first bracket 110 further includes a first reinforcing rib 111r extending from the edge of the front end of the first extension rib 111 and formed stepwise on the second piece 102 of the first housing 100. Maybe.

On the other hand, the second bracket 120 constitutes the second bracket 120 as shown in FIGS. 2, 5 and 6, along the connection portion where the first piece 101 and the second engagement means 420 meet. It may include a second support rib 121 extending parallel to the first piece 101 and the second piece 102 and contacting the first piece 301 of the third housing 300 .

Here, the second bracket 120 extends from the edge of the front end of the second support rib 121 as shown in FIGS. 2 (a), 3 (a), 5 (b), and 7 (a) to the first housing. A second reinforcing rib 122 formed stepwise on the first piece 101 of (100) may be further provided.

On the other hand, in the first housing 120, the second support ribs of the second housing 200 adjacent to each other, as shown in FIGS. 7 (b) of the second housing 200 may further include a seating step 123 formed stepwise on one side edge of the first piece 101 so that the protruding part) is seated and fixed. am.

As described above, the present invention is assembled according to the shape of the installation target surface and can be used as an external finishing material by itself, as well as having tilting and thermal bridge prevention functions that can fundamentally block heat inflow and outflow between indoor and outdoor sides. It can be seen that providing a vacuum insulation assembly is a basic technical idea.

And, of course, many other modifications and applications are possible to those skilled in the art within the scope of the basic technical idea of the present invention.

100...first housing
101...Part 1
102...Part 2
103 ... first virtual plane
104 ... second virtual plane
110 ... 1st bracket
111 ... first extension rib
111r...1st reinforcing rib
112... fixed rib
113 ... second extension rib
114 ... first support rib
120 ... 2nd bracket
121 ... second support rib
122 ... second reinforcing rib
123... Seated steps
150...Internal clamping rib
151 ... connection hole
160...external fastening rib
161 ... auxiliary connection hole
200 ... second housing
202 ... second piece of the second housing 200
300... third housing
301 ... First piece of the third housing 300
400 ... tilting joint
410 ... first engagement means
411 ... first mating extruded surface
412 ... first combined recessed surface
420 ... second engagement means
421 ... second combined recessed surface
422 ... second mating extruded surface
500...vacuum insulation
700 ... thermal bridge prevention
701 ... First blocking incision
702 ... second blocking incision
710...the first deadline
711... 1st fitting projection
712 ... first spacer
713 ... first fastening hole
714 ... 1st auxiliary fastening rib
715 ... 1st auxiliary fastening hole
720...Second Deadline
721 ... 2nd fitting projection
722 ... second spacer
723 ... second fastening hole
724 ... 2nd auxiliary fastening rib
725 ... 2nd auxiliary fastening hole

Claims (7)

a housing with both ends penetrating, including a first piece disposed on the outdoor side and a second piece disposed indoors and parallel to the first piece, and having a vacuum insulation material disposed between the first piece and the second piece;
One edge of the first piece and the second piece are interconnected to surround the vacuum insulation material and allow engagement and tilting of one of the plurality of housings (hereinafter referred to as the first housing) and an adjacent housing (hereinafter referred to as the second housing) A first engaging means for connecting the first piece and the other side edge of the second piece to each other to surround the vacuum insulation material and engage the first housing and the neighboring housing (hereinafter referred to as the third housing) separately from the second housing. and a tilting coupling part including a second engaging means allowing tilting; and
In order to prevent a thermal bridge between the outdoor side and the inside, a first blocking cutout formed to divide the first engaging means and a second blocking cutout formed to divide the second engaging means A vacuum insulation assembly having a tilting and thermal bridge preventing function, characterized in that it comprises a thermal bridge preventing part including a part.
The method of claim 1,
The first engagement means,
A first coupling protruding curved surface bent and extended from one edge of the first piece and convexly formed in a direction away from a first imaginary plane connecting the first piece and one edge of the second piece to each other;
A first coupling recessed curved surface that is bent and extended from one edge of the second piece and formed convexly in a direction approaching the first imaginary plane to be connected to the first coupling protruding curved surface,
The first blocking cutout,
Formed on the first coupling protruding curved surface or the first coupling depression curved surface;
It is formed at the connection portion of the first combining protruding curved surface and the first combining depressed curved surface,
The vacuum insulation assembly having a tilting and thermal bridge prevention function, characterized in that the first engaging means of the first housing is connected to the second engaging means of the second housing.
The method of claim 1,
The second engagement means,
A second combined depression curved surface bent and extended from the other edge of the first piece and convexly formed in a direction approaching a second imaginary plane connecting the first piece and the other edge of the second piece;
a second coupling protruding curved surface that is bent and extended from the other edge of the second piece, is convexly formed in a direction away from the second imaginary plane, and is connected to the second coupling depressed curved surface;
The second blocking cutout,
Formed on the second combined depressed curved surface or the second combined protruding curved surface;
It is formed at the connection portion of the second combined depressed curved surface and the second combined protruding curved surface,
The vacuum insulation assembly having a tilting and thermal bridge prevention function, characterized in that the second engaging means of the first housing is connected to the first engaging means of the third housing.
The method of claim 1,
The thermal bridge prevention unit,
A first closing piece made of a material having a lower thermal conductivity than the first housing and closing the open end surface of the first housing;
Protruding from the first closing piece to correspond to the inner edge shape of the open end surface of the first housing and being fitted into the inside of one end of the first housing, formed integrally with the first closing piece A first fitting protrusion,
Protruding from the first closing piece and simultaneously extending from both sides of the first fitting protruding piece and disposed at one end of each of the first blocking cutout and the second blocking cutout, the first closing piece and A first spacer integrally formed with the first fitting protrusion piece;
A second closing piece made of a material having a lower thermal conductivity than the first housing and closing the other open end surface of the first housing;
Protruding from the second closing piece to correspond to the shape of the inner edge of the open other end surface of the first housing and being fitted into the inside of the other end of the first housing, formed integrally with the second closing piece A second fitting protrusion,
Protruding from the second closing piece and extending from both sides of the second fitting protruding piece at the same time as being disposed at the other end of each of the first blocking cutout and the second blocking cutout, the second closing piece and A second spacer integrally formed with the second fitting protrusion piece;
A first fastening hole passing through a plurality of holes along the inside of the edge of the first closing piece, disposed outside the first fitting protruding piece, and through which a fastener for fixing the first closing piece to one end of the first housing passes; ,
A second fastening hole through which a plurality of holes are penetrated along the inside of the edge of the second closing piece, disposed outside the second fitting protruding piece, and through which a fastener for fixing the second closing piece to the other end of the first housing passes; ,
It is integrally formed with the first housing at a position corresponding to each of the plurality of first fastening holes and the plurality of second fastening holes along the inner surface of the first housing, and the first fastening hole and the second fastening hole are formed integrally with the first housing. A vacuum insulation assembly having a tilting and thermal bridge prevention function, characterized in that it has a connection hole disposed in a straight line with the center of the hole at the center and further includes an internal fastening rib to which the plurality of fasteners are respectively fixed to the connection hole. .
The method of claim 4,
The thermal bridge prevention unit,
A first auxiliary fastening rib extending in plurality along an outer edge of the first closing piece;
A first auxiliary fastening hole through which the fastener is inserted through each of the first auxiliary fastening ribs;
Second auxiliary fastening ribs extending in plurality along the outer edge of the second closing piece;
A second auxiliary fastening hole through each of the second auxiliary fastening ribs through which the fastener is inserted;
It is integrally formed with the first housing at a position corresponding to each of the plurality of first auxiliary fastening holes and the plurality of second auxiliary fastening holes along the outer surface of the first housing, and the first auxiliary fastening hole and the first auxiliary fastening hole A tilting and thermal bridge prevention function comprising an auxiliary connection hole disposed in a straight line with the center of the second auxiliary connection hole at the center and an external fastening rib to which the plurality of fasteners are respectively fixed to the auxiliary connection hole. A vacuum insulation assembly having a.
The method of claim 1,
a first bracket extending along a connection portion where the second piece and the first engaging means meet and supporting the second piece of the second housing;
A vacuum insulation assembly having a tilting and thermal bridge prevention function, characterized in that it further comprises a second bracket extending along the connection portion where the first piece and the second engaging means meet and supporting the first piece of the third housing. .
The method of claim 6,
A first extension rib constituting the first bracket and extending obliquely along a connection portion where the second piece and the first engaging means meet;
A fixing rib constituting the first bracket, extending in parallel with the first piece and the second piece along the distal end edge of the first extension rib, and contacting the installation target surface facing the second piece; ,
a second extension rib constituting the first bracket and obliquely extending along the edge of the distal end of the fixing rib;
a first support rib constituting the first bracket, extending parallel to the first and second pieces along the distal edge of the second extension rib, and contacting the second piece of the second housing; ,
Tilting characterized in that it comprises a second support rib constituting the second bracket, extending along a connection portion where the first piece and the second engaging means meet, and contacting the first piece of the third housing. and a vacuum insulation assembly having a thermal bridge prevention function.

Images