KR102322112B1 - deformed wire mesh integrated insulation panel and manufacturing method thereof - Google Patents

Abstract

The present invention relates to a deformed wire mesh-integrated insulation panel and a manufacturing method thereof, which comprises: an insulation material formed to have preset thickness, width and height; a pair of deformed wire meshes formed by connecting transverse deformed wires and longitudinal deformed wires continuously disposed at intervals and disposed respectively on a front surface and a rear surface of the insulation material; and a plurality of connection members connecting the deformed wire mesh on the front surface of the insulation material and the deformed wire mesh on the rear surface of the insulation material, wherein support portions which protrude with predetermined width toward the insulation material are continuously formed at intervals on each of the transverse deformed wire and the longitudinal deformed wire in the deformed wire mesh and come in contact with a surface of the insulation material to keep a predetermined distance from the deformed wire mesh to the insulation material, thereby enabling thickness of placed mortar to be uniform.

Description

Deformed wire mesh integrated insulation panel and manufacturing method thereof

The present invention relates to a thermal insulation panel, and more specifically, to increase the fire resistance performance of a wall by allowing mortar to be poured with a certain thickness, and to increase the strength of the wall by enabling smooth attachment of the mortar, It relates to a deformable wire mesh-integrated insulation panel and a method for manufacturing the same, which allow for easy connection between objects by allowing mutual support between one object and another object.

The exterior and interior walls of buildings are usually made by pouring concrete.

That is, the outer and inner walls of the building can be formed by installing the formwork on the inner and outer sides of the frame formed through the reinforcing bar connection, then injecting and curing the concrete into the formwork.

In addition, an insulating material is attached to one surface of the outer and inner walls of the building to have heat insulating properties, and by attaching a finishing material such as brick or tile to the surface of the insulating material, the appearance may be beautiful.

At this time, since it takes considerable labor and time to form a frame through reinforcing bars and attach an insulating material, there is a problem in that the efficiency of the wall forming operation is lowered.

In order to solve this problem, a 'wire mesh integrated insulation panel' as disclosed in Korean Patent Registration No. 10-2101510 has been used in recent construction sites.

The wire mesh-integrated insulation panel has a wire mesh attached to the front and rear surfaces of the insulation, so the product is connected and installed in the longitudinal direction without any work such as forming a frame and attaching the insulation material, and then simply pouring mortar on the surface of the building. An outer wall and an inner wall may be formed.

However, since most of the conventional wire mesh-integrated insulation panels have irregularities formed in the insulation, the mortar pouring thickness is not constant due to the irregularities, so the fire resistance performance is lowered, that is, the mortar pouring thickness is relatively thin at the uneven protruding part of the insulating material. There was a problem that the fire resistance performance of the wall was lowered.

In addition, since most of the conventional wire mesh-integrated insulation panels have smooth surfaces of the insulating material and the wire mesh, the adhesion of mortar did not meet expectations, so there was a problem in that the strength of the wall was lowered.

In addition, most of the conventional wire mesh-integrated insulation panels were connected in the longitudinal direction as one end of one end and one end of the other were abutted. There was a problem in that it was difficult to connect between objects.

For the above reasons, in the relevant field, it is attempted to develop a wire mesh-integrated insulation panel and a manufacturing method thereof that can increase the fire resistance performance of the wall, increase the strength of the wall, and facilitate the connection between objects, So far, satisfactory results have not been obtained.

Republic of Korea Patent Registration No. 10-2101510

The present invention has been proposed to solve the problems of the prior art as described above, so that the fire resistance performance of the wall can be increased by allowing the mortar to be poured with a certain thickness, and the strength of the wall by enabling the mortar to be attached smoothly. It is an object of the present invention to provide a deformable wire mesh integrated insulation panel and a method for manufacturing the same, which allows for easy connection between objects by enabling mutual support between one object and another object.

In order to achieve the above object, the present invention

insulation formed in a preset thickness, width and height; A pair of deformed wire meshes formed through the connection of continuous deformed wire in the transverse direction and the deformed wire in the longitudinal direction at intervals, respectively, disposed on the front and rear surfaces of the insulating material; and a plurality of connecting members connecting the deformed wire mesh on the front side of the insulator and the deformed wire mesh on the rear surface of the insulator, wherein the deformed wire mesh has a constant width toward the insulating material on each of the horizontally deformed wire and the longitudinally deformed wire. It proposes a deformed wire mesh-integrated insulation panel, characterized in that the support portions protruding to be continuously formed at intervals to maintain a constant distance between the support portions and the insulation material as each support portion comes into contact with the surface of the insulation material.

The heat insulating material includes an embossed portion formed on the surface.

Each of the transversely deformed wire and the longitudinally deformed wire of the deformed wire mesh includes a plurality of ribs protruding from an outer circumferential surface to a predetermined height.

The deformed wire mesh has one end in the width direction protruding from one end in the width direction of the insulator, one end in the width direction of the deformed wire mesh on the front side of the heat insulating material protrudes to one side in the width direction of the insulation, and one end in the width direction of the deformed wire mesh at the rear of the heat insulating material is the The insulation material protrudes to the other side in the width direction.

The connecting member is connected in an oblique direction, at least one of which is inclined downward, and at least one is inclined upward.

In addition, in order to achieve the above object, the present invention,

It is made through the connection of an insulating material having a preset thickness, width and height and a continuous transverse deformed wire and a longitudinal deformed wire at intervals, and a support of a certain width is provided in each of the transverse and longitudinal deformed wires Forming a heat insulating material and a deformed wire network to form a continuously arranged deformed wire network with a step; The deformed wire mesh is disposed on the front and rear surfaces of the insulating material, respectively, so that one end of the deformed wire mesh in the width direction of the front side of the heat insulator protrudes from one end of the deformed wire mesh in the width direction of the insulator, and one end of the deformed wire mesh in the width direction of the rear surface of the heat insulator is the insulator A deformed wire mesh arrangement step of disposing to protrude from the other end in the width direction; and a plurality of connecting members extending in an oblique direction between the deformed wire mesh on the front side of the insulator and the deformed wire mesh on the rear surface of the insulator to connect the deformed wire mesh on the front side of the insulator and the deformed wire wire network on the back side of the insulator. We propose a method of manufacturing a deformed wire mesh integrated insulation panel, comprising: a.

The heat insulating material and the deformed wire mesh forming step may include: an embossing part forming step of forming an embossing part on the surface of the insulating material; and a rib forming step of forming ribs protruding to a predetermined height from an outer circumferential surface on each of the deformed wire mesh in the transverse direction and the deformed wire in the longitudinal direction of the deformed wire mesh.

In the connecting member of the deformed wire mesh connecting step, at least one is inclined downward, and at least one is inclined upward, and may be coupled to the deformed wire network by welding.

In the deformed wire mesh-integrated insulation panel according to the present invention, support portions protruding with a predetermined width toward the insulating material are continuously formed at intervals on each of the deformed wire mesh in the transverse direction and the deformed wire in the longitudinal direction of the deformed wire mesh. As a certain distance is maintained between the insulating material and the deformed wire mesh as it comes into contact, the thickness of the mortar pouring can be made constant, so that the fire resistance performance of the wall can be improved.

In addition, in the deformed wire mesh integrated insulation panel according to the present invention, an embossing part is formed on the surface of the insulating material, and ribs are formed on the horizontally deformed wire and the longitudinally deformed wire of the deformed wire mesh, the insulating material and the insulating material and Since the mortar can be easily attached to the surface of the deformed wire mesh, the strength of the wall can be increased.

In addition, in the deformed wire mesh integrated insulation panel according to the present invention, one end of the deformed wire mesh in the width direction of the front side of the insulating material protrudes to one side in the width direction of the insulating material, and one end of the deformed wire mesh in the width direction of the rear side of the insulation protrudes to the other side in the width direction of the insulating material. When connecting, the product can be easily connected because mutual support is made by the deformed wire mesh projecting to one side and the other side in the width direction of the insulation material.

In addition, in the deformed wire mesh integrated insulation panel according to the present invention, a plurality of connecting members connecting the deformed wire mesh on the front of the insulating material and the deformed wire mesh on the back of the insulator are connected in an oblique direction, at least one of which is inclined downward, and at least one is upward. By forming an inclination bar, the flow of the connecting member is suppressed on the insulating material, so that the connection of the deformed wire mesh by the connecting member can be made stably.

1 is an exploded perspective view for explaining the structure of a deformed wire mesh one-type insulation panel according to the present invention.
2 is an exemplary view showing the connection between the deformed wire mesh integrated insulation panel according to the present invention.
3 is an exemplary view showing a cross-sectional shape of a wall formed using a deformed wire mesh one-type insulation panel according to the present invention.
4 is an exemplary view showing one form of ribs formed in the horizontally deformed wire and the longitudinally deformed wire of the deformed wire mesh in the deformed wire mesh integrated insulation panel according to the present invention.
5 is an exemplary view showing other forms of ribs formed in the deformed wire mesh in the transverse direction and the longitudinal deformed wire of the deformed wire mesh in the integrated insulation panel of the deformed wire mesh according to the present invention.
6 is an exemplary view showing the connection of the deformed wire wire network through the connecting member in the integrated wire wire mesh insulation panel according to the present invention.
7 is a schematic process diagram for explaining the manufacturing method process of the deformed wire mesh integrated insulation panel according to the present invention.

Hereinafter, the present invention will be described in detail based on the accompanying drawings.

As shown in FIG. 1, the deformed wire mesh integrated insulation panel (A) according to the present invention includes a heat insulating material (10); Deformed wire mesh (20); and a connection member 30 .

The thermal insulation material 10 of the present invention is formed with a preset thickness, width and height.

Therefore, the deformable wire mesh integrated insulation panel (A) according to the present invention by the heat insulating material (10) has thermal insulation properties.

At this time, the insulating material 10 includes the embossed portion 11 formed on the surface, so that the mortar 100, which is poured in the subsequent wall formation process, is caught in the embossed portion 11, and is closely attached to the surface of the insulator 10. can be

On the other hand, if the heat insulating material 10 is formed of a heat insulating material and has heat insulating properties, it may be any type of conventional material, and may be a Styrofoam board as an example.

The deformed wire mesh 20 of the present invention is formed through the connection of the horizontally deformed wire 21 and the longitudinally deformed wire 22 continuous at intervals, and is disposed on the front and rear surfaces of the insulating material 10, respectively.

Therefore, not only the rigidity of the deformed wire mesh integrated insulation panel A according to the present invention is secured by the deformed wire mesh 20, but also a certain mortar 100 pouring space is secured between the insulation material 10 and the insulator 10 in the subsequent wall formation process.

At this time, the deformed wire mesh 20 is a horizontally deformed wire 21 and a longitudinally deformed wire 22, respectively, with a support part 23 protruding with a predetermined width toward the heat insulating material 10 is continuously formed at an interval, so that each support part As the 23 is in contact with the surface of the insulator 10 , a certain distance may be maintained between the insulator 10 and the insulator 10 .

And each of the horizontally deformed wire 21 and the longitudinally deformed wire 22 of the deformed wire mesh 20 includes a plurality of ribs 24 protruding at a constant height from the outer circumferential surface, so that the mortar 100 to be poured in the subsequent wall formation process ) may be closely attached to the surface of the deformed wire mesh 20 as it is caught on the rib 24 .

Here, the rib 24 may be formed by any conventional method as long as it can protrude at a predetermined height from the outer peripheral surfaces of the horizontally deformed iron wire 21 and the longitudinally deformed iron wire 22, and is formed on the rib 24 A detailed description thereof will be omitted.

And the deformed wire mesh 20, one end in the width direction protrudes from one end in the width direction of the heat insulating material 10, and one end in the width direction of the deformed wire mesh 20 in the front side of the heat insulating material 10 protrudes to one side in the width direction of the insulator 10, the heat insulating material (10) One end in the width direction of the deformed wire mesh 20 at the rear side protrudes to the other side in the width direction of the insulating material 10, so that when connecting between the deformed wire mesh integrated insulation panel A according to the present invention in the future, the deformed iron on the front side of the insulating material 10 of one object As the protruding portion of the wire mesh 20 and the protruding portion of the deformed wire mesh 20 on the rear surface of the insulator 10 is caught on the front and rear surfaces of the insulation 10 of another adjacent object, mutual support may be achieved.

The connecting member 30 of the present invention is provided in plurality to connect the deformed wire mesh 20 on the front side of the insulator 10 and the deformed wire wire network 20 on the back side of the insulator 10 .

Therefore, the unintentional separation of the deformed wire mesh 20 from the front and rear surfaces of the insulating material 10 is prevented by the connection member 30 .

At this time, the connection member 30 is connected in an oblique direction, at least one of which forms a downward inclination, and at least one forms an upward inclination, so that flow inhibition can be achieved on the insulating material 10 .

And the coupling of the connecting member 30 and the deformed wire mesh 20 is made by welding, so that the coupling state of the connecting member 30 and the deformed wire mesh 20 can be firmly maintained.

Here, the connection member 30 penetrates the heat insulating material 10 and is welded to the deformed wire wire network 20 on the front side of the heat insulating material 10 and the deformed wire wire network 20 on the back side of the heat insulating material 10 by welding. It may be of any kind, and an example thereof may be a deformed iron wire.

On the other hand, as shown in FIG. 7, the method of manufacturing a deformed wire mesh integrated insulation panel (A) according to the present invention includes a heat insulating material and a deformed wire mesh forming step (S1); Deformed wire mesh arrangement step (S2); and a deformed wire network connection step (S3);

In the insulating material and deformed wire mesh forming step (S1) of the present invention, the insulator 10 having a preset thickness, width and height, and the horizontally deformed wire 21 and the longitudinal deformed wire 22 are continuously connected at intervals. Doedoe, the horizontally deformed wire 21 and the longitudinally deformed wire 22, respectively, to form a deformed wire mesh 20 in which the support portions 23 of a certain width are continuously arranged at intervals.

At this time, the insulating material and the deformed wire mesh forming step (S1) includes the embossing portion forming step (S1-1) of forming the embossed portion 11 on the surface of the heat insulating material 10, so that the heat insulating material by the embossing portion forming step (S1-1) (10) An embossed portion 11 may be formed on the surface.

And the insulating material and the deformed wire mesh forming step (S1) is formed of ribs forming ribs 24 protruding at a constant height from the outer circumferential surface in each of the deformed wire 21 and the deformed wire 22 in the horizontal direction of the deformed wire mesh 20. By including the step (S1-2), the rib 24 may be formed in the deformed wire mesh 20 by the rib forming step (S1-2).

In the deformed wire mesh arrangement step (S2) of the present invention, the deformed wire wire network 20 is disposed on the front and rear surfaces of the insulating material 10, respectively, and one end of the deformed wire wire network 20 in the width direction of the front side of the insulation 10 is the width of the insulation 10 It is arranged to protrude from one end in the direction, and one end in the width direction of the deformed wire mesh 20 on the rear surface of the insulator 10 is arranged to protrude from the other end in the width direction of the insulator 10 .

In the deformed wire mesh connecting step (S3) of the present invention, a plurality of connecting members 30 connected in an oblique direction between the deformed wire wire network 20 on the front side of the insulating material 10 and the deformed wire wire network 20 on the rear side of the insulating material 10 are combined. To connect the deformed wire mesh 20 on the front of the insulator 10 and the deformed wire mesh 20 on the back of the insulator 10 .

At this time, the connecting member 30 of the deformed wire mesh connecting step (S3), at least one of which forms a downward inclination, at least one forms an upward inclination, is coupled to the deformed wire mesh 20 by welding.

When described in detail with respect to the wall formation using the deformable wire mesh integrated insulation panel (A) according to the present invention as follows.

The deformed wire mesh integrated insulation panel (A) according to the present invention is installed in a standing state at the wall formation point.

Therefore, the wall can be formed by pouring the mortar 100 on the front and rear surfaces of the deformed wire mesh integrated insulation panel (A) according to the present invention erected at the wall formation point.

At this time, the deformed wire mesh integrated insulation panel (A) according to the present invention includes a heat insulating material 10 and a deformed wire mesh 20, and the wall has thermal insulation performance by the heat insulating material 10, and the deformed wire mesh 20 The rigidity of the wall can be secured by this.

However, when the thickness of the mortar 100 pouring before and after the insulating material 10 is non-uniform during the wall formation process, the fire resistance performance of the wall may be reduced.

However, in the deformed wire mesh 20 of the present invention, the supporting portions 23 protruding with a predetermined width toward the insulating material 10 on each of the horizontally deformed wire 21 and the longitudinally deformed wire 22 are continuously formed at intervals. As each support part 23 comes into contact with the surface of the heat insulating material 10, a certain distance can be maintained between the insulating material 10 and the mortar 100 before and after the heat insulating material 10 as shown in FIG. ) Since the pouring thickness can be made constant, the fire resistance performance degradation of the wall due to the non-uniformity of the mortar 100 pouring thickness can be prevented.

And when the attachment of the mortar 100 to the insulating material 10 and the deformed wire mesh 20 in the process of forming the wall is insufficient, the strength of the wall may be reduced.

However, in the present invention, the insulating material 10 includes an embossed portion 11 formed on the surface, and the deformed wire mesh 20 is a transversely deformed wire 21 and a longitudinally deformed wire as shown in FIG. 4 or 5 . (22) The rib (24) protruding from the outer circumferential surface to a certain height, the mortar 100, which is poured in the process of forming the wall, is the embossed portion 11 of the insulating material 10 and the rib of the deformed wire mesh (20) ( 24), since it can be closely attached to the surface of the insulating material 10 and the deformed wire mesh 20, a decrease in the strength of the wall due to insufficient attachment of the mortar 100 can be prevented.

The deformed wire mesh-integrated insulation panel (A) according to the present invention as described above can form a continuous wall by connecting one object and another object.

In this case, if the consecutively arranged objects fall down, it may be difficult to connect the objects.

However, in the deformed wire mesh integrated insulation panel (A) according to the present invention, the deformed wire mesh 20 has one end in the width direction protruding from one end in the width direction of the insulator 10, more specifically, the width of the deformed wire mesh 20 in the front of the insulation 10 One end in the width direction protrudes to one side in the width direction of the insulator 10, and one end in the width direction of the deformed wire mesh 20 at the rear side of the insulator 10 protrudes to the other side in the width direction of the insulator 10, as shown in FIG. When connecting, the protruding part of the insulating material 10 front of one object and the deformed wire mesh 20 protruding from the insulation 10 and the rear deformed wire mesh 20 of one object are caught on the front and rear sides of the insulating material 10 of another adjacent object, so the deformed wire mesh 20 ) The mutual support between objects can be made by the jamming of the protruding part, so that the object can be prevented from falling down due to the forward and backward flow, thereby making it easy to connect the objects.

And the deformed wire mesh integrated insulation panel (A) according to the present invention can be stably connected to the deformed wire wire network 20 on the front side of the insulating material 10 and the deformed wire wire network 20 on the back side of the insulating material 10 .

That is, in the present invention, the connecting member 30 connecting the deformed wire mesh 20 on the front side of the insulating material 10 and the deformed wire wire network 20 on the rear side of the insulating material 10 is connected in an oblique direction as shown in FIG. 6 , At least one is inclined downward, and at least one is inclined upward, the flow of the connecting member 30 is suppressed on the insulating material 10 so that the connection of the deformed wire mesh 20 by the connecting member 30 is stably made. can

In addition, since the coupling of the connecting member 30 and the deformed wire mesh 20 is made by welding, the coupling state of the connecting member 30 and the deformed wire mesh 20 can be firmly maintained.

On the other hand, when described in detail with respect to the manufacturing method of the deformed wire mesh integrated insulation panel (A) according to the present invention as follows.

First, the insulating material 10 and the deformed wire mesh 20 are formed.

That is, the insulating material 10 having a preset thickness, width and height is formed by the forming step (S1) of the insulating material and the deformed wire mesh of the present invention, and the horizontally deformed wire 21 and the longitudinally deformed wire that are continuous at intervals The deformed wire mesh 20 is formed through the connection of 22, and in which the support portions 23 of a certain width are continuously arranged at intervals on each of the horizontally deformed wire 21 and the longitudinally deformed wire 22, respectively. .

At this time, the heat insulating material and the deformed wire mesh forming step (S1) includes an embossing portion forming step (S1-1) of forming an embossed portion 11 on the surface of the heat insulating material 10, and the embossed portion forming step (S1-1) The embossed portion 11 may be formed on the surface of the heat insulating material 10 by this.

And the insulating material and the deformed wire mesh forming step (S1) is formed of ribs forming ribs 24 protruding at a constant height from the outer circumferential surface in each of the deformed wire 21 and the deformed wire 22 in the horizontal direction of the deformed wire mesh 20. Including the step (S1-2), the rib 24 may be formed in the deformed wire mesh 20 by the rib forming step (S1-2).

Next, the deformed wire mesh 20 is disposed on each of the front and rear surfaces of the insulating material 10 .

That is, the deformed wire mesh 20 is disposed on the front and rear surfaces of the insulating material 10, respectively, by the deformed wire mesh arrangement step (S2) of the present invention.

At this time, one end of the deformed wire mesh 20 in the width direction of the front side of the heat insulator 10 is disposed to protrude from one end in the width direction of the insulator 10, and the one end in the width direction of the deformed wire mesh 20 at the back of the insulator 10 is the insulator 10 It is arranged to protrude from the other end in the width direction.

Next, the deformed wire mesh 20 of the front and rear surfaces of the insulating material 10 is connected.

That is, a plurality of connecting members 30 connected in an oblique direction between the deformed wire mesh 20 on the front side of the insulating material 10 and the deformed wire mesh 20 on the rear side of the insulating material 10 by the deformed wire mesh connecting step (S3) of the present invention. is coupled, the deformed wire mesh 20 on the front of the insulator 10 and the deformed wire mesh 20 on the back of the insulator 10 are connected.

At this time, at least one of the connecting members 30 is inclined downward, and at least one is inclined upward, and is coupled to the deformed wire mesh 20 by welding.

Since the present invention as described above is not limited to the above-described embodiments, it can be changed within the scope without departing from the gist of the present invention claimed in the claims, and such changes are the present invention defined by the following claims. fall within the protection scope of the invention.

10: insulation material 11: embossed part
20: Deformed wire mesh 21: Transversely deformed wire
22: longitudinal deformed wire 23: support
24: rib 30: connecting member
100: Mortar A: Deformed wire mesh integrated insulation panel
S1: Insulation material and deformed wire mesh forming step S1-1: Embossing part forming step
S1-2: Rib forming step S2: Deformed wire mesh arrangement step
S3: Deformed wire mesh connection step

Claims (8)

insulation formed in a preset thickness, width and height;
A pair of deformed wire meshes formed through the connection of continuous deformed wire in the transverse direction and the deformed wire in the longitudinal direction at intervals, respectively, disposed on the front and rear surfaces of the insulating material; and
Containing; and
In the deformed wire network, support portions protruding with a predetermined width toward the insulating material are continuously formed at intervals on each of the transversely deformed wire and the longitudinal deformed wire, and as each support portion is in contact with the surface of the insulator, it is in contact with the insulation. A certain distance is maintained between
The heat insulating material includes an embossed portion formed on the surface,
Each of the horizontally deformed wire and the longitudinally deformed wire of the deformed wire network includes a plurality of ribs protruding at a constant height from the outer peripheral surface,
The deformed wire mesh is formed to have the same width and height as the insulating material, and as one end in the width direction is spaced apart by a preset width from one end in the width direction of the insulator to the other end, the other end in the width direction is to one side or the other side in the width direction of the insulating material Deformed wire mesh integrated insulation panel, characterized in that each protrudes. delete delete delete According to claim 1,
The connecting member is connected in an oblique direction, at least one of which forms a downward inclination, and at least one of which forms an upward inclination. As a method of manufacturing a deformed wire mesh integrated insulation panel according to claim 1 or 5,
It is made through the connection of an insulating material having a preset thickness, width and height and a continuous transverse and longitudinal deformed wire at intervals, and a support of a certain width is provided in each of the transverse and longitudinal deformed wires. Forming a heat insulating material and a deformed wire network to form a continuously arranged deformed wire network with a step;
The deformed wire mesh is disposed on the front and rear surfaces of the insulating material, respectively, and one end of the deformed wire mesh formed with the same width and height as the insulating material in the width direction is spaced apart by a preset width from one end in the width direction of the insulating material toward the other end in the width direction of the deformed wire mesh. A deformed wire mesh arrangement step of disposing the other end to protrude to one side or the other side in the width direction of the insulating material, respectively; and
A deformed wire network connecting step of connecting a plurality of connecting members extending in an oblique direction between the deformed wire mesh on the front side of the insulator and the deformed wire mesh on the rear surface of the insulator to connect the deformed wire mesh on the front side of the insulator and the deformed wire wire network on the back side of the insulator ; Method for manufacturing a heterogeneous wire mesh integrated insulation panel, characterized in that it comprises a. 7. The method of claim 6,
The insulating material and the deformed wire mesh forming step may include: an embossing part forming step of forming an embossing part on the surface of the insulating material; and a rib forming step of forming ribs protruding at a predetermined height from an outer circumferential surface of each of the deformed wire mesh in the transverse direction and the deformed wire in the longitudinal direction of the deformed wire mesh. 7. The method of claim 6,
At least one of the connecting members of the deformed wire mesh connecting step is inclined downward, at least one is inclined upward, and is coupled to the deformed wire mesh by welding. Method of manufacturing an integrated insulation panel.

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