KR101340300B1 - Prefab module wall system - Google Patents

Abstract

The present invention relates to a prefabricated module wall system and, more specifically, to a prefabricated module wall system capable of securing thermal efficiency by combining an outer wall to a structure, forming a wall, and preventing air flow caused by a connection part between outer walls. The prefabricated module wall system includes a structure for supporting the loading of a building and an outer wall including connection protrusions at the inner surface to be connected to the structure.

Description

Prefab Module Wall System

The present invention relates to a prefabricated module wall system, and more particularly, to a prefabricated module wall system that combines an outer wall with a structure to form a wall and prevents the flow of airflow by a coupling site between the outer walls to ensure thermal performance. will be.

The prefabrication method has excellent construction properties in that the process is simpler and the construction work is minimized than the existing construction method. Most of the work is done in factories, such as frame construction, interior construction, facility construction, and electrical construction, which take up a considerable amount of work from the existing construction methods. , Is reduced.

Since most of the processes performed in the factory are not affected by the change in weather, it can be said that it is very advantageous compared to the existing methods in which field construction is limited by rain or cold.

In general, when the wall is formed in the prefabricated module, a screw is used to couple the outer wall to the structure. Fixing the wall through the screw through the outer wall and the structure when the screw is removed, the screw is rotated in the reverse direction and the outer wall or structure of the outer shell is often bent out of the role of the outer wall or structure in many cases. In addition, when a screw is used in the structure of the outer wall, heat transfer occurs through the screw between the outer wall and the structure, resulting in severe thermal bridges, and it is difficult to secure airtightness.

In addition, in order to form a wall of the prefabricated module, a plurality of outer walls are coupled, but there is a problem in that heat bridges are generated by moving the heat of the outside air to the structural portion by a coupling portion due to the coupling between the outer walls.

The present invention has been made to solve the above problems, an object of the present invention is to provide a prefabricated module wall system that can be reused to form a wall without using a screw.

Still another object of the present invention is to provide a prefabricated module wall system which prevents heat flow from occurring at the coupling portion of the wall by preventing heat flow of outside air.

Prefabricated module wall system according to an aspect of the present invention for achieving the above object includes a structure for supporting the load of the building, and an outer wall having a plurality of engaging projections on the inner side for coupling with the structure. Can be.

The structure may include a plurality of coupling holes at positions corresponding to the plurality of coupling protrusions to accommodate the coupling protrusions.

The coupling hole may include an insertion portion to which the coupling protrusion is coupled, and a fixing portion to fix the coupling protrusion.

The outer wall body may be coupled to the structure by the coupling protrusion is inserted into the insertion portion is fixed to the fixed portion by the vertical load of the outer wall body.

In addition, the prefabricated module wall system according to an aspect of the present invention for achieving the above object is coupled to the structure for supporting the load of the building, the structure, and the inside to prevent heat cross between the outdoor and indoor It may include an outer wall provided with a heat insulating material, a sheet surrounding the heat insulating material, and an exterior material surrounding the sheet and supporting the heat insulating material.

The exterior member may include an extension part that extends laterally than the heat insulating material, and an accommodation part accommodating the extension part on an opposite side of the extension part.

The extension part may be provided with an airtight material to improve the airtightness with the receiving portion when received in the receiving portion.

The heat insulating material may be used by stacking a plurality in order to increase the heat insulating effect.

Between a plurality of the heat insulating material may be provided with an interior material for reducing the emissivity.

The outer wall may have a coupling protrusion to couple with the structure.

The structure may include an insertion portion into which the coupling protrusion is inserted, and a fixing portion to which the coupling protrusion inserted into the insertion portion is moved downward and fixed by a vertical load.

According to the prefabricated module wall system according to the present invention, the coupling protrusion of the outer wall is inserted into the coupling hole of the structure and is fixed to the structure by the vertical load of the outer wall so that it can be reused.

In addition, an extension part and a receiving part may be provided on the outer wall to prevent heat flow of the outside air.

1 is a perspective view showing a prefabricated module wall system according to an embodiment of the present invention.
FIG. 2 is a sectional view of the prefabricated module wall system shown in FIG. 1; FIG.
3 is a perspective view showing a structure according to an embodiment of the present invention.
Figure 4 is a perspective view of the outer wall according to an embodiment of the present invention.
5 is a cross-sectional view showing a process in which the outer wall body is coupled to the structure according to an embodiment of the present invention.
6 to 7 is a cross-sectional view showing a state in which a plurality of outer wall body is coupled according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a prefabricated module wall system according to an embodiment of the present invention.

1 is a perspective view showing a prefabricated module wall system according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing a prefabricated module wall system shown in FIG.

1 to 2, the prefabricated module wall system according to an embodiment of the present invention may include a structure 200 supporting a load of a building and an outer wall 100 coupled to the structure 200. Can be.

Prefabricated modules are manufactured at the factory and assembled on site. The prefabricated module may form a building in such a way that the structure supporting the load, such as the column 10, beams, walls, etc., is manufactured at the factory with accurate dimensions and assembled at the site.

The structure 200 may be fixed to the pillar 10 after assembling a skeleton such as a column 10 and a beam manufactured in a factory. The structure 200 may be formed as a wall by assembling a plurality between the pillars 10 of the prefabricated module, it may be divided and supported by the column 10 by the load of the upper. Therefore, the structure 200 may use a material having a predetermined strength capable of supporting the load of the upper portion.

For example, when the structure 200 fixed to the pillar 10 is not a structure capable of supporting the load of the upper portion, the thickness of the pillar 10 may be thick or the size of the pillar 10 may be increased. Therefore, the structure 200 may be formed to a predetermined thickness to serve as a load bearing wall and support the load of the upper portion together with the pillar 10.

The outer wall body 100 is coupled to the structure 200 and the heat insulating material 120 is provided to prevent thermal cross-linking between the outdoor and indoor, the sheet 130 surrounding the heat insulating material 120 and the sheet ( It may be provided with a packaging material 110 for wrapping the 130 to surround the insulating material (120).

The heat insulator 120 may be used to overlap a plurality in order to increase the heat insulation effect. In addition, an interior material 121 may be provided between the plurality of heat insulating materials 120 to lower the emissivity. The interior material 121 may be made of a material such as aluminum having a low emissivity. In addition, the interior material 121 may use a moisture-permeable paper or moisture-proof paper that absorbs moisture in order to prevent condensation due to a temperature difference between the outdoor and the indoor.

For example, when the insulation material 120 is overlapped with each other and the interior material 121 is not provided, condensation may occur due to a temperature difference between an outdoor or indoor location, and moisture or moisture may be generated between the heat insulation material 120. Therefore, by using the interior material 121 of a material that absorbs moisture, the moisture or moisture may be removed in advance to protect the heat insulating material 120 that is weak to moisture. In addition, when the interior material 121 is formed of aluminum having low emissivity, a higher effect may occur than using the same heat insulating material 120. In addition, when the interior material 121 having a low emissivity is used, a higher effect may be generated than using only the heat insulating material 120 when maintaining the indoor temperature.

The sheet 130 may surround the heat insulator 120 to prevent breakage and the like, which occurs when the heat insulator 120 comes into contact with the foreign material, and may prevent moisture from reaching the heat insulator 120.

The exterior member 110 may include a coupling protrusion 300 that may be coupled to the structure 200. The coupling protrusion 300 may be formed on the interior side of the exterior member 110, and provided with a plurality of coupling protrusions 300 to increase binding force with the structure 200.

The exterior material 110 may be formed of a material having a low emissivity and a predetermined strength, such as an aluminum panel. The exterior member 110 may serve as a cover capable of supporting the inner heat insulating material 120 and may be formed to a predetermined thickness so as not to be damaged by an external impact.

3 is a perspective view showing a structure 200 according to an embodiment of the present invention, Figure 4 is a perspective view showing an outer wall 100 according to an embodiment of the present invention, Figure 5 is an embodiment of the present invention Cross-sectional view showing a process in which the outer wall body 100 is coupled to the structure 200 according to.

3 to 4, the prefabricated module wall system according to the exemplary embodiment of the present invention has a structure 200 fixed to the pillar 10 and a coupling protrusion 300 to couple with the structure 200. It may be provided with an outer wall 100 having a.

As shown in FIG. 3, the outer wall body 100 may include an exterior member 110 and a heat insulator 120 inside the exterior member 110.

The exterior material 110 may be divided into outdoor exterior materials 112 and 110 and interior exterior materials 111 and 110, and the interior exterior materials 111 and 110 are coupled to the pillars 10 and the structure 200. It may be provided with a coupling protrusion 300.

The outdoor exterior materials 112 and 110 may include an extension part 113 extending to one side than the heat insulating material 120, and the extension part 113 is accommodated on the other side of the extension part 113. It may be provided with a receiving portion 114 that can be.

The coupling protrusion 300 provided in the interior and exterior materials 111 and 110 may be formed extending from the surface of the interior and exterior materials 111 and 110 to the interior side.

The coupling protrusion 300 may be formed of a protrusion head 320 extending from the interior and exterior materials 111 and 110 and a protrusion head 310 formed at an end of the protrusion head 320. The cross section of the protrusion head 320 may be formed in various shapes such as a circle, a square, and the like, and the protrusion head 310 may be formed in a shape of a circle having a larger size than the protrusion head 320. In addition, the length of the protrusion head 320 may be the same as the thickness of the structure 200 is coupled to the exterior member 110.

For example, when the length of the protrusion head 320 extending from the exterior member 110 is smaller than the thickness of the structure 200, the protrusion head 310 of the coupling protrusion 300 is connected to the structure 200. When the protrusion head 310 is fixed to the structure 200 when the length of the protrusion head 320 is longer than the thickness of the structure 200, the protrusion head 320 may be fixed to the structure 200. Since a space is generated between the 200 and the exterior member 110, the coupling force between the structure 200 and the exterior member 110 may be reduced.

In addition, the coupling protrusion 300 may be provided with a plurality of the interior and exterior materials 111 and 110 to increase the coupling force between the structure 200 and the exterior material 110 when coupled with the structure 200.

As shown in FIG. 4, the structure 200 may be fixed to the pillar 10 to support the structure of the prefabricated module.

The structure 200 may include a coupling hole 400 that may be coupled to the coupling protrusion 300. The coupling hole 400 is an insertion portion 410 into which the protrusion head 310 of the coupling protrusion 300 is inserted, and the protrusion head 320 moves and the protrusion head 310 is caught so that the outer wall body 100 is caught. ) And a fixing part 420 to fix the structure 200.

The coupling hole 400 may be formed at a position corresponding to the coupling protrusion 300, and the coupling hole 400 is also formed at the pillar 10 to which the structure 200 is fixed, so that the outer wall body 100 is formed. May be fixed to the column 10 as well as the structure 200.

For example, when the outer wall 100 is coupled to only the structure 200, when the structure 200 is fixed to the pillar 10, the structure 200 and the structure 200 are loaded by the load of the outer wall 100. The pillar 10 may be separated. Therefore, a separate coupling hole 400 may be formed in the pillar 10 so that the outer wall body 100 may be combined with the pillar 10 to improve the bonding force between the outer wall body 100 and the structure 200. .

As shown in FIG. 5, the coupling protrusion 300 and the structure 200 may be fixed by a vertical load of the outer wall body 100. Therefore, the outer wall 100 may be reused when removed after coupling to the structure 200.

Coupling protrusions 300 formed on the interior and exterior materials 111 and 110 of the outer wall 100, the outer wall 100 to the coupling hole 400 of the structure 200, as shown in Figure 5 (a) Lifting may be coupled to the coupling hole 400.

And, as shown in (b) of FIG. 5, the coupling head can be inserted into the insertion portion 410 of the coupling hole 400, the coupling hole as shown in (c) of FIG. In order to move the coupling protrusion 300 inserted into the 400 to the fixing part 420 of the coupling hole 400, the vertical load of the outer wall body 100 acts as shown in FIG. When the force applied to lift the outer wall 100 is removed, the outer wall 100 may move downward while the coupling protrusion 300 may move to the fixing part 420. Therefore, the outer wall 100 may not be separated from the structure 200 unless a force rising upward.

On the contrary, when the outer wall body 100 is separated from the structure 200, the outer wall body 100 is lifted to move the position of the coupling protrusion 300 from the fixing part 420 to the insertion part 410. Can be.

Therefore, the outer wall 100 may be reused by being separated from the structure 200 without deformation or breakage.

In addition, since the coupling protrusion 300 of the outer wall body 100 does not penetrate the structure 200, external heat transferred by the outer wall body 100 does not enter the room through the structural member, thereby preventing thermal bridges. .

6 to 7 are cross-sectional views showing a state in which a plurality of outer wall body 100 is coupled according to an embodiment of the present invention.

As shown in FIGS. 6 to 7, when the outer wall 100 of the prefabricated module wall system according to an embodiment of the present invention is coupled between the extension part 113 and the accommodation part 114 to prevent thermal bridges. It may be provided.

In order to construct a wall of the prefabricated module using the outer wall 100, a plurality of outer walls 100 may be used.

The outer wall body 100 may include a heat insulating material 120, a sheet 130 surrounding the heat insulating material 120, and an exterior material 110 surrounding the sheet 130.

The exterior member 110 may be divided into outdoor exterior materials 112 and 110 and interior exterior materials 111 and 110, and the exterior exterior materials 112 and 110 extend to one side than the thermal insulation material 120. A portion 113 may be provided, and a side portion different from the extension portion 113 may include an accommodation portion 114 in which the extension portion 113 may be accommodated.

The extension part 113 includes the extension part 113 and the accommodation part 114 when the first hermetic material 510 and the extension part 113 formed on the interior side are accommodated in the accommodation part 114. It may be provided with a second hermetic material 520 for ensuring the airtightness of the contact.

The first hermetic material 510 may use a nonwoven fabric, an expansion band, or the like, and may be in contact with the side surface of the accommodating part 114 in the long side direction.

The second hermetic material 520 may be used as a sealant caulking and prevents heat of outside air from being transferred to the inside when contacted with the shortest end of the extension part 113 and the side surface in the short side direction of the receiving part 114. can do.

When using a plurality of the outer wall 100, the method of coupling between the outer wall 100 is a method of coupling between the outer wall 100 at the corner of the prefabricated module and a method of coupling between the outer wall 100 to form a wall Can be distinguished.

As a method of coupling between the outer wall body 100 in the corner portion of the prefabricated module is accommodated in the short side direction of the outer wall body 100 at the shortest end of the outer wall body 100 formed vertically as seen in cross section as shown in FIG. The portion 114 may be formed. After fixing the vertically formed outer wall 100 to the column 10 and the structure 200 may be coupled to the column 10 and the structure 200 horizontally formed outer wall (100). In this case, the extension part 113 may be accommodated in the accommodation part 114, and the side surfaces of the first airtight material 510 and the long side direction of the accommodation part 114 may be in contact with each other. . When the extension part 113 is accommodated in the accommodation part 114, a gap between the accommodation part 114 and the extension part 113 may be filled with a second hermetic material 520 to improve airtightness. .

As shown in FIG. 7, when the outer wall body 100 is coupled to the structure 200, and the other outer wall body 100 is coupled to the outer wall body 100, the outer wall body 100 is connected to the receiving part 114 formed in the long side direction of the outer wall body 100. The extension 113 of the can be combined to be accommodated.

The outer wall 100 may be formed in a different position of the receiving portion 114 of the wall and the side wall of the corner portion of the prefabricated module to improve airtightness, when the outer wall 100 is coupled between the receiving portion 114 and By extending the 113, the external heat flow can be bent in a Z shape rather than in a straight direction, thereby preventing the heat flow. In addition, the airtight material 500 may be used at a position where heat flow occurs to ensure airtightness.

In the above described the prefabricated module wall system according to an embodiment of the present invention, the spirit of the present invention is not limited to the embodiments presented herein. Those skilled in the art, who understands the spirit of the present invention, can readily suggest other embodiments by adding, changing, deleting, adding, or the like of components within the scope of the same idea, I would say.

10: pillar 100: outer wall
120: insulation 130: sheet
200: structure 300: coupling protrusion
400: coupling hole 500: airtight material

Claims (11)

delete delete delete delete A structure supporting the load of the building,
Coupled to the structure, and provided with an outer wall body having a heat insulating material provided inside to prevent heat cross between the outdoor and indoor, a sheet surrounding the heat insulating material, and an exterior material surrounding the sheet and supporting the heat insulating material,
The exterior material includes an outdoor exterior material having an extension part extending laterally than the heat insulating material and an accommodation part accommodating the extension part on an opposite side of the extension part, and an outdoor interior material having a plurality of coupling protrusions for engaging with the structure. ,
The extension portion is provided with an airtight material to improve the airtightness with the receiving portion when accommodated in the receiving portion,
The structure is provided with a plurality of coupling holes in a position corresponding to the plurality of coupling projections to accommodate the plurality of coupling projections,
The coupling hole includes an insertion portion into which the coupling protrusion is inserted, and a fixing portion to which the coupling protrusion inserted into the insertion portion is moved downward and fixed by a vertical load.
The outer wall body is a prefabricated module wall system, characterized in that the coupling protrusion is inserted into the insertion portion is fixed to the fixing portion by the vertical load of the outer wall body and coupled to the structure.
delete delete 6. The method of claim 5,
The insulating material prefabricated module wall system, characterized in that a plurality of overlapping use to increase the thermal insulation effect.
The method of claim 8,
A prefabricated module wall system, characterized in that it has a built-in material for reducing the emissivity between the plurality of the heat insulating material.


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