KR20150066248A - Insulation wall system and method for constructing thereof - Google Patents

Abstract

The present invention relates to an insulation wall system and a construction system thereof using a vacuum heat insulator. The insulation wall system comprises: a plurality of anchor bolts installed in a wall; a plurality of vacuum heat insulators supported by the anchor bolts to be installed in the wall; a plurality of planar pins coupled to the anchor bolts by a screw-coupling method to fixate the vacuum heat insulators; an adhesive applied on the planar pin; and a plurality of finishing boards fixated and installed through the adhesive on the planar pin. According to the present invention, the insulation wall system enables installation of the vacuum heat insulator and a smoothing work of the wall to be easily served and provides the thin wall and the easy construction work.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an insulation wall system,

The present invention relates to a heat insulation wall system, and more particularly, to a semi-wet insulation wall system using a flat plate and a construction method thereof.

In insulation wall construction, vacuum insulation provides a high thermal insulation performance of less than 0.0039 W / mk, which is more than eight times the insulation performance of conventional insulation. The heat insulating performance of the vacuum insulating material is expressed by maintaining the degree of vacuum, and the heat insulating performance may be deteriorated due to cutting, breakage or necrosis at the construction site. Therefore, the vacuum insulation material should be factory-manufactured to the size after field inspection and care should be taken when transporting it in the field. In spite of the fact that the vacuum insulation material provides high heat insulation performance, it is not widely used due to high manufacturing cost, storage, handling, and construction problems.

However, as insulation insulation standards for walls are becoming higher and more attention is being paid to the construction of insulation walls due to the problems of heating and cooling costs, there is an increasing interest in vacuum insulation materials that can greatly improve the insulation performance without reducing the internal area of the building .

1 is a sectional view schematically showing an example of a heat insulating wall system using a conventional vacuum insulating material. The illustrated heat insulating wall system has a structure in which a vacuum insulating material 3 is attached to a wall 1 using a bond 2 and a gypsum board 7 is fixed to the vacuum insulating material 3 with a bond 2 . However, when the vacuum insulating material is adhered to the concrete wall by the bond, there is a fear that the amount of applied bond is not sufficient or the adhesive property of the bond is weakened under a high temperature construction condition such as a summer season, and the vacuum insulating material is separated from the wall. In addition, as the high temperature and low temperature are repeated in the summer and winter season, the expansion and contraction of the bond may be repeated and the vacuum insulation may be detached.

2 is a cross-sectional view schematically showing another example of a heat insulating wall system using a conventional vacuum insulating material. In the heat insulating wall system shown in the figure, a vacuum insulator 3 is attached to a wall 1 by a bond 2, and the upper and lower runners 4 and 5 are arranged at regular intervals in front of the vacuum insulator 3 And a plurality of channel studs 6 are supported by the channel studs 6 and the gypsum boards 7 are fixed to the channel studs 6 by nails 8. In such an insulated wall system, since the gypsum board 7 is fixed by the nail 8 to the stud 6 provided at a predetermined distance in front of the vacuum insulator 3, the vacuum insulator 3 is held by the nail 8 It is not damaged. However, such a heat insulating wall system also has a problem that the vacuum insulating material is detached due to the bonding of the vacuum insulating material by the bond, and the steel structure is installed on the front side of the vacuum insulating material. In addition, the use of the channel stud 6 not only thickens the wall, but also requires an upper and lower runner for supporting the channel stud, resulting in increased installation cost.

In order to solve the adhesion of the vacuum insulation material by the bond and to simplify the construction, a heat insulation wall system as shown in FIG. 3 has been developed. In the illustrated heat insulating wall system, the wall 10 is provided with anchor bolts 20 at the position of the vacuum insulating material joint, the vacuum insulating material 30 is supported by the anchor bolts, and the CR bracket is inserted into the anchor bolt 30 After the UGO M-bar 60 is installed, the gyro board 80 is fixed to the M-bar with screws 70. In such an insulation wall system, since the vacuum insulation material is provided by the anchor bolts, there is no fear of disassembling the vacuum insulation material and there is no need to use the stud, which is advantageous in that the construction is simple. However, such a heat insulating wall system has a problem that the smoothness of the wall is difficult to adjust due to the smoothness of the anchor bolt and the CR bracket when the gypsum board finishes.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide a heat insulating wall system using a vacuum insulator, which is free from the risk of dislodgement of a vacuum insulation material against a concrete wall, It is an object of the present invention to provide an insulation wall system and a construction method thereof.

According to an aspect of the present invention, there is provided an insulating wall system comprising: a plurality of anchor bolts installed on a wall; A plurality of vacuum insulation members supported by the wall and supported by the plurality of anchor bolts; A plurality of flat-plate fins attached to the anchor bolts to fix the vacuum insulation members; An adhesive applied on the flat fins; And a plurality of finishing plates fixedly installed through the adhesive on the flat pins.

That is, the heat insulating wall system of the present invention is a semi-wet wall system in which a vacuum insulating material is fixed by an anchor bolt by using a flat-plate-shaped fin coupled to an anchor bolt, and the finished plate is adhered by a bonding adhesive. Since the heat insulating material can be stably fixed by the anchor bolt and the plate type pin and the finishing plate is installed by the adhesive, the wall smoothness can be easily adjusted by finely adjusting the depth to which the finished plate is adhered, Since the wall is thin and construction is easy because it is not used.

In a preferred embodiment of the present invention, the plurality of anchor bolts are arranged to be positioned at the corner joint portions of the neighboring vacuum insulating materials, thereby minimizing thermal bridging.

Preferably, a protective cap for protecting the vacuum insulator may be interposed between the vacuum insulator and the flat-plate fin.

In addition, it is preferable that the flat-plate fin is formed as a horizontal member having a plurality of gratings formed therein to efficiently fix the vacuum heat insulating material and to facilitate application of the adhesive. More preferably, the planar fin may be a butterfly shape having convex sides on both sides.

The plate-like fins can be attached to the ends of the anchor bolts in various ways. In one embodiment, screw holes are formed at the center of the plate-like fins and threads are formed at the ends of the anchor bolts, . In addition, preferably, a snap fastener is formed at a center portion of the flat plate-shaped fin and a snap groove is formed at an end portion of the anchor bolt, so that the snap fastener can be fastened in a one-touch manner. In this case, there is an advantage that it is easy to install even in a narrow space such as an outlet box or a door because there is no need to rotate the flat-type pin for screw connection.

In order to achieve the object of the present invention, a method for constructing a heat insulating wall using a vacuum insulator is characterized in that a plurality of anchor bolts are fixedly installed on a wall to be vacuum-insulated according to a design drawing in consideration of a wall finishing thickness and a size of a vacuum insulator ; Placing a vacuum insulator between the fixed anchor bolts, inserting the vacuum insulator protecting cap into the anchor bolts, and fixing the vacuum insulator by fastening the flat pins to the anchor bolts; Applying an adhesive to the flat fins; And attaching the finishing plate to the flat fin through an adhesive to adjust smoothness of the finished finishing plate.

As described above, in the heat insulating wall system according to the present invention, the vacuum heat insulating material is fixed by the anchor bolts, so that the vacuum heat insulating material can be easily attached, and the finished plate material is coated with the adhesive on the flat- It is easy to install and easy to work on wall smoothness. In addition, since the studs and the like are not used, the wall is thin and construction is easy.

1 is a sectional view of a heat insulating wall system using a conventional vacuum insulator.
2 is a sectional view of a heat insulating wall system using another conventional vacuum insulating material.
3 is a cross-sectional view of a heat insulating wall system using another conventional vacuum insulating material.
4 is a sectional view of a heat insulating wall system using a vacuum insulating material according to an embodiment of the present invention.
FIG. 5 is a perspective view of an embodiment of a flat-type fin used in the heat insulating wall system of FIG.
6 is a perspective view of another embodiment of a flat-type pin used in the heat insulating wall system of FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The present invention can be variously modified in various ways and will be described in detail through embodiments. It is to be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but on the contrary, is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise.

Also, unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the meaning of the context in the relevant art and, unless explicitly defined herein, are to be interpreted as ideal or overly formal Do not.

4, the heat insulating wall system using vacuum insulation according to an embodiment of the present invention includes a plurality of anchor bolts 120 fixed to predetermined portions of a wall 110, A vacuum insulator protection cap 140 and a flat plate fin 150 which are fastened to the anchor bolt 120 for fixing the vacuum insulation material 130; Shaped fin 150 and an end plate 180 attached to the flat-plate-shaped fin by the adhesive 160. The adhesive 160 is applied to the fin 150,

The wall 110 may be a concrete retaining wall such as a building, but it is not limited thereto. The heat insulating wall system of the present invention can be used not only for the above concrete retaining wall but also for any structure and material wall requiring heat insulation Can be installed.

The anchor bolts 120 are installed on the wall 110 to be vacuum-insulated at regular intervals according to the size of the vacuum insulator 130. The anchor bolts 120 may be secured to the wall 110 by drilling holes formed therein and then installed with the knife block.

As is well known, the anchor bolt 120 is formed with threads on both sides of the bolt member, so that it can be fixed to the wall by using one screw thread, and members other than the other screw thread are screwed It is a bolt with a structure that can be fastened and fixed.

The anchor bolts 120 are fixed to the wall 110 so that the anchor bolts 120 are positioned at the corner joint portions of the neighboring vacuum insulation members 130 attached to the wall 110. [ That is, if the vacuum insulation material to be installed is 450 mm × 900 mm, the anchor bolts 120 are spaced apart by 450 mm in the lateral direction of the wall 110 and 900 mm in the longitudinal direction. As described above, the anchor bolt is installed only at the joint portion of the vacuum insulator adjacent thereto, so that the thermal bridge phenomenon can be minimized.

The vacuum insulation material 130 is a new type of insulation material having a thermal conductivity of 0.0039 W / mK or less through a special treatment such as vacuum or the like with fumed silica or glass wool as the main material and has a heat insulating performance of 8 times or more as compared with a general insulation material .

In the present invention, since the vacuum insulation material 130 is not attached to the wall 110 by the bond but is fixed by the anchor bolt 120 and the flat plate-like fin 150 described below, the vacuum insulation material can be easily and reliably .

The flat plate fin 150 is fixed to the anchor bolt 120 so that the vacuum insulator 130 positioned between the wall 110 and the flat plate fin 150 can be tightly fixed to the wall 110. This makes it possible to attach the vacuum insulating material 130 to the wall 110 without using a bond.

The flat pins 150 may be fastened to the anchor bolts 120 in various ways, for example, as shown in FIG. That is, the flat plate-like fin 150 is formed as a horizontal member having a screw hole 151a for fastening with the anchor bolt 120 at the center thereof, and the plate-like pin 150 is placed on the anchor bolt 120 The pin 150 is fastened to the anchor bolt 120 by the screw thread 151b of the anchor bolt 120 and the screw hole 151a of the flat pin 150. As a result, 110 and the flat plate-like fin 150 are fixed.

6 shows another embodiment of the structure in which the plate-like fins 150 are anchored to the anchor bolts 120. As shown in Fig. A snap fit 152a is formed at the center of the plate type pin 150 and a snap groove 152b is formed at the end of the anchor bolt 120 so that the plate type pin 150 is inserted into the anchor bolt 120 ) So as to be coupled in a one-touch manner. That is, in such a coupling structure, the plate-like pin 150 does not need to be rotated for screwing, and therefore, a minimum space for rotation is not required. Therefore, the construction is much easier due to such a coupling structure, and it is also possible to easily install the parts where there are space constraints such as an outlet box or a door.

When the vacuum insulation panel 130 is fixed using the flat fins 150 as described above, the vacuum insulation panel 140 is first inserted into the anchor bolts 120 to protect the vacuum insulation panel 130 , And the flat plate-like fin (150). The protection cap 140 may be formed of rubber, plastic, silicon or the like. By using the protection cap 40, it is possible to prevent the vacuum insulation material 130 from being damaged when the flat- .

After the vacuum insulator 130 is fixed by the flat plate fin 150 as described above, the adhesive 160 for fixing the finishing plate 180 is directly applied on the flat plate fin 150. Therefore, it is preferable that the flat-type fin 150 is formed as a convex butterfly on both sides as shown in FIG. 5 so that the vacuum insulator 130 can be effectively fixed and the adhesive 160 can be easily applied. In addition, a plurality of gratings 153 may be formed on the horizontal member to facilitate the application of the adhesive 160.

As the finishing plate 180, a gypsum board, a CRC board, a magnesium board or a plywood board may be used. As the adhesive 160, a gypsum bond or the like may be used. That is, since the finishing plate 180 is attached by the adhesive 160 coated on the flat plate fin 150, the smoothness of the wall can be easily adjusted by finely adjusting the depth to which the finishing plate 180 is adhered. In addition, since it is not necessary to use a stud or an M-bar, the construction can be simplified and the thickness of the heat insulating wall can be reduced.

A method of constructing a heat insulation wall system using vacuum insulation according to an embodiment of the present invention is as follows.

First, an installation position of a plurality of anchor bolts 120 is indicated on a wall 110 where a vacuum insulation material is to be installed, using an indentation or the like. At this time, the anchor bolts 120 are positioned at the corner joint portions of the neighboring vacuum insulating material 130 in order to minimize the thermal bridging. For this purpose, considering the thickness of the finishing plate and the size of the vacuum insulating material, And displays the installation position.

Then, the anchor bolt 120 is installed at the anchor bolt installation position of the wall 110. At this time, the anchor bolt 120 forms a hole in the wall 110 by a drilling operation, and then fixes the hole with the knife block. Thereafter, the vacuum insulating material 130 is installed between the anchor bolts, and the vacuum insulating material 130 is fixed using the vacuum insulating material protecting cap 140 and the flat plate fin 150. Specifically, the vacuum insulator 130 is positioned between the anchor bolts, the vacuum insulator protection cap 140 is inserted into the anchor bolts, and the flat plate fin 150 is fastened to the anchor bolts, (110).

Then, after the adhesive 160 is applied to the flat plate fin 150, the finished plate 180 is attached in consideration of flatness.

As described above, the heat insulating wall system using the vacuum insulation material according to the present invention is a dry insulation method in which the vacuum insulation material 130 is installed on the wall 110 without using a bond and the dry process using the adhesive material 160 such as a bond The anchor bolt 120 and the flat plate fin 150 can easily attach the vacuum insulator 130 and the adhesive agent coated on the flat plate fin 150 Since the finishing plate 180 is fixed by the finishing plate 160, the smoothness of the wall is easily worked, and since the studs and the like are not used, the wall is thin and the construction is simple.

In the foregoing, the invention has been described in an illustrative manner. It is to be understood that the terminology used herein is for the purpose of description and should not be regarded as limiting. Various modifications and variations of the present invention are possible in light of the above teachings. Therefore, unless otherwise indicated, the present invention may be practiced freely within the scope of the claims.

110: wall 120: anchor bolt
130: vacuum insulator 140: protective cap
150; Flat-plate type pin 151a: Flat-plate type screw
151b: Thread of anchor bolt 152a: Snap fastener of flat plate pin
152b: Snap groove of anchor bolt 153: Grid of flat plate pin
160: Adhesive 180: Finishing plate

Claims (9)

A plurality of anchor bolts installed on the wall;
A plurality of vacuum insulation members supported by the wall and supported by the plurality of anchor bolts;
A plurality of flat-plate fins attached to the anchor bolts to fix the vacuum insulation members;
An adhesive applied on the flat fins; And
And a plurality of finishing plates fixedly installed through the adhesive on the flat pins. The method according to claim 1,
Wherein the plurality of anchor bolts are disposed to be positioned at corner joint portions of neighboring vacuum insulation members. The method according to claim 1,
And a protective cap for protecting the vacuum insulation material is interposed between the vacuum insulation material and the flat plate-like fin. 4. The method according to any one of claims 1 to 3,
Wherein the flat-plate-shaped fin is formed of a horizontal member having a plurality of gratings formed therein. 4. The method according to any one of claims 1 to 3,
Wherein the flat-type fin has a butterfly shape. 4. The method according to any one of claims 1 to 3,
Wherein a screw hole is formed at a central portion of the flat plate fin, a thread is formed at an end of the anchor bolt, and the flat plate pin is screwed to the anchor bolt. 4. The method according to any one of claims 1 to 3,
Wherein a snap fastener is formed at a central portion of the flat plate fin, and a snap groove is formed at an end of the anchor bolt, and the plate pin is fastened to the anchor bolt in a one-touch manner. As a method for constructing a heat insulating wall using a vacuum insulating material,
a) fixing a plurality of anchor bolts to the wall to which the vacuum insulation is to be applied according to the design drawing in consideration of the wall finishing thickness and the size of the vacuum insulation;
b) placing a vacuum insulation material between the fixed anchor bolts, inserting the vacuum insulation cap into the anchor bolts, and fixing the vacuum insulation with the anchor bolts;
c) applying an adhesive to the flat fins;
and d) attaching the finishing plate to the flat fin through an adhesive and adjusting the smoothness of the finish finishing plate. 9. The method of claim 8,
Wherein the plurality of anchor bolts are arranged to be positioned at corner joint portions of neighboring vacuum insulation members.

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