KR101498580B1 - Thermal and Seismic Strengthening Stone Construction and Maintenance Method - Google Patents

Abstract

The present invention relates to a method of constructing and reinforcing insulation and earthquake-proof stone to a wall formed on inner and outer portions of a building. The method includes the steps of: installing a plurality of support members having an anchor and a positioning member to a wall at a predetermined position; installing a plurality of stone panels to upper and lower portions of the support member; filling a foamed insulator in a space formed between the wall and the stone panel; and jointing between the stone panels with a sealing agent. The method may include applying a primer to the wall or stone panel. The step of applying the primer is carried out after the step of installing the stone panel and before the step of filling the foamed insulator in case of existing building, and is carried out before the step of installing the support member in case of new building.

Description

TECHNICAL FIELD [0001] The present invention relates to a method for constructing and reinforcing an insulation and a seismic stone,

The present invention relates to a method of constructing and reinforcing a heat insulating and earthquake-resistant stone, and more particularly, to a method of constructing a stone panel and a stone panel structure, In the building which is reinforced with insulation and seismic performance by applying the adhesive material to reinforce the adhesion of the foamed synthetic resin between the panel and the wall and the filling step of the foam insulation, the stone panel is applied to the wall, The present invention relates to a method for installing and reinforcing an insulating and earthquake-resistant stone that stabilizes a structure of a stone wall including a step of installing a means, a step of installing a stone panel, a step of filling a foam insulation, and a joint treatment step.

Generally, after the structure is formed, the construction is finished by using stone, paint, wood or the like with the inside and outside finishing work.

As shown in FIGS. 1A to 1C, the stone wall finishing using the stone in the finishing work is carried out by adhering the panelized heat insulation material such as Styrofoam to the wall W and fixing the supporting means for supporting the stone panel to the wall The heat insulating material is removed at a position where the supporting means is to be fixed to expose the wall.

Thereafter, the supporting means is fixed to the exposed wall, and the stone panel is bound to the end of the supporting means using a binding pin.

The method of the prior art as described above has the disadvantages of removing the heat insulating material, and the position of the supporting means is indicated by feeding the heat insulating material. However, after the heat insulating material is removed, And the position where the heat insulating material was removed had an additional problem that the heat insulating performance was deteriorated, so that it was necessary to additionally reinforce the process.

Further, when the position of the supporting device is not precise, there is a structural problem that the stone panel is unstably fixed.

Further, in the process of fixing the supporting means to the stone panel, a predetermined space is generated between the heat insulating material and the stone panel by the fixing means, and the air flow through the heat insulating material has a problem in insulation. In addition, the gap between the heat insulating material and the connecting part and the gap between the wall and the heat insulating material, which are generated when the heat insulating material is attached to the wall, are also reduced by the air flow. In addition, when the fire occurs, the space generates a stacking phenomenon, and there is a problem that the heat insulating material is burned.

In addition, when a stone panel is piled up as a block from the lower part to the upper part through the supporting means, the impact of the lowermost stone panel and the uppermost stone panel is continuously absorbed, and all the stone panels are simultaneously impacted.

In this case, when the stone panel is cracked or broken due to the impact, it may lead to the fall of the stone, which may cause personal injury.

Meanwhile, there has been an invention in which foamed synthetic resin is injected between a wall and an exterior finishing material to secure the heat insulation performance and seismic performance. However, after a lapse of time, the peeling phenomenon occurs between the foamed synthetic resin and the exterior finishing material.

Further, there is a problem that the dust generated in the production process of the stone panel further deteriorates the adhesion force with the foamed synthetic resin.

Further, conventionally, in order to inject the foamed synthetic resin, there has been a problem of piercing the injection holes between the external finishing materials at a predetermined height, injecting the foamed synthetic resin into the injection holes, sealing the injection holes again, There is an additional problem that the heat insulation performance and the seismic performance are deteriorated when voids that do not fill the foamed synthetic resin are generated.

Also, in the case of an underground structure, there is a problem that seismic performance is not achieved due to occurrence of separation of the foamed synthetic resin and the wall due to a large amount of moisture.

In addition, in the case of the completed stone wall structure, there is a problem that the stone can be detached when an earthquake occurs because the earthquake-resistant stone construction method is not applied.

On the other hand, in recent years, the insulation standard according to the building method has been strengthened, and the thickness of the heat insulating material has to be thicker, resulting in inefficiency in space utilization where the wall thickness of the building necessarily becomes thick.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a stonewalling apparatus capable of fixing a supporting means at an accurate position, filling a foam insulating material to secure structural stability of a stone panel, It is possible to secure the seismic performance and the heat insulating performance and to prevent the peeling phenomenon by enhancing the adhesion force between the wall and the stone panel and the foam insulating material, to easily fill the foamed heat insulating material, to absorb the impact, And it is an object of the present invention to provide a method of constructing and reinforcing an insulating and earthquake-resistant stone that can secure the efficiency of space utilization because the thickness is not increased.

In order to accomplish the above object, there is provided a method of constructing and reinforcing a heat insulating and earthquake-resistant stone according to the present invention, comprising the steps of: applying a stone panel (20) to a wall (W) The method M of constructing comprises a supporting means mounting step (S100) of installing a plurality of supporting means (10) including the anchor (11) and the position adjusting member (12) at a predetermined position on the wall (W) A stone panel installing step (S200) of installing a plurality of stone panels (20) on the upper and lower portions of the supporting means (10); A foam insulating material filling step S300 of filling the space S formed between the wall W and the stone panel 20 with the foam insulating material 30; And a joint treatment step (S400) of jointing the plurality of stone panels (20) by using a sealant (40). An adhesion enhancer (P) is applied to the wall (W) or the stone panel The step of applying the adhesive strengthening agent is performed after the step of installing the stone panel (S200) and before the step S300 of filling the foamed insulating material in the case of the building to which the adhesive strengthening agent is applied, (S100) in the case of a losing building.

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The adhesive strengthening agent applying step may include a step of applying an adhesion enhancing agent including an injection port 61 and an endoscope 62 to the space S formed between the wall W and the stone panel 20, An injecting device injecting step (S251) of injecting the injecting device (60); And an adhesive strengthening agent injecting step (S252) for injecting the adhesive strengthening agent (30) onto the wall (W) or the stone panel (20) by using the adhesive strengthening agent injecting device (60).

In addition, the supporting means installation step S100 may include a drilling position display step S110 for displaying a drilling position for installing the supporting means 10 on the wall W; A perforation hole forming step (S120) of forming a perforation hole (H) at the perforation position; And a supporting step (S130) of attaching the anchor (11) to the hole (H) and to fix the position adjusting member (12).

The stone panel installation step S200 includes a stone panel binding step S210 for binding the stone panel 20 to the upper and lower portions of the position adjustment member 12; A position adjustment step S220 of adjusting the front, rear, left and right positions of the stone panel 20 using the position adjustment member 12; And a supporting means binding step (S230) of binding the anchor (11) of the supporting means (10) and the position adjusting member (12).

The filling step S300 of filling the foamed thermal insulating material is performed by injecting an injection device 31 including an injection port 31a and an endoscope 31b into a space S formed between the wall W and the stone panel 20 Injecting an injecting device (S310); And a foaming heat insulating material filling step (S320) of filling the foam insulating material 30 from the lower part to the upper part of the space part S using the injection device 31.

The wire installation step S150 further includes a wire installation step S150 before the stone panel installation step S200 after the supporting means installation step S100, A step (S151) of a wire fixing member provided in the means (10); A wire bonding step (S152) of binding the wire (52) to the wire fixing member (51); And a wire pin step (S153) comprising a wire pin (53) on the wire (52).

The heat insulating and quartz stone wall SW according to one embodiment of the present invention is a stone wall SW formed by installing a stone panel 20 on a wall W formed on the inside and outside of a building, The wall SW is bound to a plurality of support means 10 including the anchor 11 and the position adjustment member 12 on the wall W and a plurality of stone panels And the space portion S formed between the wall W and the stone panel 20 is filled with the foam insulating material 30 and the sealing material 20 is sandwiched between the plurality of stone panels 20 40 are provided on the inner surface of the wall W or the stone panel 20, and an adhesion enhancer P is applied to the inner surface of the wall W or the stone panel 20.

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Further, the stone panel 20 is burned and the surface area of the application of the adhesion promoter (P) is enlarged.

In addition, the anchor 11 is provided with an elongated anchor hole 11a, and the position adjusting member 12 is provided with an elongated position adjusting hole 12a, And a fixing pin 12b is provided at an end of the position adjusting member 12 so as to be fixed to the fixing hole 21 formed at the upper and lower portions of the stone panel 20.

A vibration absorbing pad 14 is provided on the upper part of the position adjusting member 12 and a stone panel 20 is bonded to the upper part of the vibration absorbing pad 14.

In addition, the stone panel 20 is provided with a separation prevention pin 22 to prevent the foaming heat insulating material 30 from separating from the stone panel 20.

A wire fixing member 51 is provided on the supporting means 10 and a wire 52 is coupled to the wire fixing member 51. A wire pin 53 is provided on the wire 52 Thereby preventing the wall W and the foamed heat insulating material 30 from being separated from each other.

As described above, according to the method of constructing and reinforcing a heat insulating and earthquake-resistant stone according to the present invention, it is possible to omit the process of removing the heat insulating material to fix the supporting means by filling the foam insulating material at a later time, So that the support means can be fixed at the correct position.

Therefore, there is no need to apply a heat insulating material and an unnecessary process can be omitted, and the heat insulating performance and the seismic performance can be ensured.

Further, by using the position adjusting member of the supporting means, it is possible to construct a structurally stable stone wall without any step even if the wall is bent or the surface is uneven.

In addition, it is possible to prevent a space between the wall and the stone panel from being filled by filling the foam insulating material, thereby ensuring a tight thermal insulation performance, and preventing a stacking phenomenon due to the space when a fire occurs.

In addition, the present invention can be applied not only to walls of a building to be newly or expanded, but also to walls of a building to which the present invention is applied.

Furthermore, even when an earthquake occurs, the foamed insulating material and the stone panel adhere to each other to absorb the impact of the stone panel, thereby eliminating the problem that the impact is transmitted to the adjacent stone panel.

Therefore, the stone panel can be cracked or broken due to the impact, and the stone can be prevented from falling down, and the occurrence of human life damage caused by the stone panel can be prevented.

On the other hand, it is possible to prevent the peeling of the stone panel by applying and absorbing the adhesive strengthening agent to the wall or the stone panel while using the foamed heat insulating material to strengthen the adhesion with the foamed heat insulating material.

In addition, the application work can be effectively performed by using the adhesive strengthening agent injection device including the endoscope and the injection port.

In addition, it is possible to effectively fill the foam insulating material using an injection device including an endoscope and an injection port, and also to confirm the internal state of the space part during the injection process, thereby preventing voids that are not filled with the foam insulating material, And the seismic performance can be improved.

In addition, even in the case of an underground structure containing a large amount of moisture, the wires can be bundled, and the wire can be provided on the wire to strengthen the adhesion between the foam insulation and the wall, thereby preventing the foam insulation.

In addition, it is possible to prevent the escape phenomenon of the foamed heat insulating material by securing the adhesion force between the foamed heat insulating material and the stone panel by providing the release panel on the stone panel.

Thereby, even if the thickness of the heat insulating material is not made thick, the heat insulating performance can be ensured and the space utilization efficiency can be obtained.

FIGS. 1A and 1B are a perspective view and an exploded perspective view showing a stone wall according to the related art; FIG.
1C is a sectional view showing a stone wall according to the prior art.
FIG. 2A is a perspective view showing a stone wall according to an embodiment of the present invention; FIG.
FIG. 2B is an exploded perspective view showing a stone panel according to an embodiment of the present invention. FIG.
FIG. 2C is a perspective view illustrating a wire installation step according to an embodiment of the present invention; FIG.
FIG. 2d is a perspective view illustrating a step of applying an adhesion enhancer according to an embodiment of the present invention; FIG.
FIG. 2E is a perspective view illustrating a step of filling foamed insulation according to an embodiment of the present invention. FIG.
Figures 3a and 3b are exploded perspective and perspective views illustrating support means according to various embodiments of the present invention.
FIG. 4 is a sectional view showing a stone wall according to an embodiment of the present invention. FIG.
5 is a block diagram showing a method of constructing a stone according to the present invention.

Embodiments of the present invention will now be described with reference to the accompanying drawings.

The prior art method of stonewalling a stanchion comprises the steps of attaching an outstretched panel-like thermal insulation material such as styrofoam to the wall W as shown in Figs. 1A to 1C and fixing the support means for supporting the stone panel to the wall The wall panel is exposed by removing the heat insulating material at a position where the means is to be fixed, the supporting means is fixed to the exposed wall body, and the stone panel is bound to the end portion of the supporting means using a binding pin.

That is, after the heat insulating material is provided, the supporting means is fixed and a stone panel is installed. At this time, in the process of fixing the supporting means to the stone panel, a predetermined space has to be generated between the heat insulating material and the stone panel by a fixing means such as a bolt.

As shown in FIG. 5, the method of constructing and reinforcing the heat insulating and earthquake-resistant stone of the present invention includes a step of applying an adhesive strengthening agent, a step of installing a supporting means S100, a step of installing a stone panel S200, And a joint processing step S400.

At this time, the wall W of the present invention can be applied not only to a wall W of a building to be expanded and contracted but also to a wall W of a building to which the wall W is applied. In the claims of the present invention, But the scope of rights of the present invention is not limited depending on the time of construction of the wall W. [

That is, unlike the prior art, as shown in FIGS. 2A to 2E, the foam panel 30 is filled in the space S after the stone panel 20 is installed.

The process of removing the heat insulating material to fix the supporting means 10 is omitted so that the wall W and the stone panel 20 are filled with the foamed heat insulating material 30, It is possible to prevent the space from being spaced apart from each other, thereby ensuring a tight thermal insulation performance.

At this time, the step of installing the supporting means (S100) is a step of installing a plurality of supporting means (10) including the anchor (11) and the position adjusting member (12) at a predetermined position on the wall (W)

It is possible to construct a structurally stable stone wall without any step even if the wall W is bent or the surface is uneven by using the position adjusting member 12 of the supporting means 10. [

The step of installing the stone panel (S200) is a step of installing a plurality of stone panels (20) on the upper and lower portions of the supporting means (10).

The step S300 of filling foam insulation after the step S200 of installing the stone panel comprises filling the space S formed between the wall W and the stone panel 20 with the foam insulation 30 to be.

This makes it possible to prevent a space from being formed between the wall W and the stone panel 20 by filling the foamed thermal insulating material 30 to ensure a tight thermal insulation performance and to prevent a stuck- have.

Furthermore, even when an earthquake occurs, the foamed thermal insulating material 30 and the stone panel 20 come into close contact with each other to absorb the impact of the stone panel 20, thereby eliminating the problem that the impact is transmitted to the adjacent stone panel 20 It is possible to prevent the stone panel 20 from being cracked or broken due to the impact and causing the stone to fall down or causing the damage to the human life.

In addition, the joint processing step S400 is a step of jointing the plurality of stone panels 20 using a sealing material 40.

The sealing material 40 can be made of silicon or the like and can prevent the foam insulating material 30 from being exposed from the outside air through the space between the stone panels 20, (20). ≪ / RTI >

The method may further include a step of applying an adhesive strengthening agent for arranging the surface of the wall W facing the stone panel 20 and applying the adhesive strengthening agent P.

4, it is preferable to use a primer or a permeable adhesion promoting material as the adhesion enhancer (P), and the adhesion enhancer (P) is applied to the wall W and the stone panel 20 and the foam insulation 30 can be strengthened to prevent the separation phenomenon.

The conventional foamed synthetic resin has a problem that deterioration of the wall and the stone panel occurs over time to deteriorate the heat insulation performance and the seismic performance.

This is caused by the fact that the expansion ratio of the foamed synthetic resin, the wall and the stone panel varies with the temperature change, or the dust generated in the production process of the stone panel is reduced due to the adherence to the foamed synthetic resin.

Therefore, the adhesion enhancer (P) deposits dust or foreign matter of the stone panel (20) and the wall (W) and infiltrates to a certain depth of the wall (W) or the stone panel (20) to alleviate the difference It is possible to prevent the phenomenon that the foamed synthetic resin 30 is peeled from the wall W and the stone panel 20.

On the other hand, the stone panel 20 is burned to make the surface area of the application of the adhesion enhancer (P) wider.

Generally, the stone panel 20 is processed using a cutting device, and the surface is often smooth. The smooth surface has a problem that the adhesion with the foamed thermal insulating material 30 is low.

When the burnishing of the stone panel 20 is performed on the stone panel 20, fine irregularities are formed on the surface to widen the surface area in contact with the foamed thermal insulating material 30 and the adhesion enhancer P is more aggressively applied to the stone panel 20, There is an effect that it can penetrate.

In this case, the application step of the adhesive strengthening agent can be applied to both the building to be constructed and the construction to be stretched and expanded. In the case of a new and expanded building, Is previously made in the stone panel (20) or the wall (W).

That is, in the case of applying the adhesion enhancer P to the wall W, the adhesion enhancer P is applied after the wall W is applied, and the adhesion enhancer P is applied to the stone panel 20 The adhesion enhancing agent P is applied to the surface of the stone panel 20 before the stone panel 20 is installed.

On the other hand, in the case of a building constructed in the past, the application step of the adhesion enhancer may include an injecting device injection step (S251) and an adhesion enhancing agent injection step (S252).

The injecting device injecting step S251 is a step of injecting an adhesive strengthening agent injecting device 60 including an injection port 61 and an endoscope 62 into a space S formed between the wall W and the stone panel 20 .

The coating operation can be performed while confirming the space S with the naked eye by using the bonding agent injector 60 including the endoscope 62 and the jetting port 61 as shown in FIG. There is a possible advantage.

The step S252 of injecting the reinforcing agent is a step of injecting the reinforcing agent 30 onto the wall W or the stone panel 20 using the adhesive enhancer injector 60. [

It is preferable that the jetting port 61 of the adhesive enhancing agent jetting device 60 is provided in both directions so as to be simultaneously applied to the wall W and the stone panel 20.

Meanwhile, the supporting means mounting step S100 may include a drilling position indicating step S110, a perforation hole forming step S120, and a supporting means decelerating step S130.

The puncturing position display step S110 is a step of displaying a puncturing position for installing the supporting means 10 on the wall W. At this time, it is preferable that the surface of the wall W is filled with food to display its position.

In the prior art, the position of the support means is indicated by feeding the heat insulator. However, after the heat insulator is removed, there is a problem in that the support means can not be fixed at the correct position due to disappearance of the food.

On the other hand, the present invention has an advantage that the support means can be fixed at the correct position by marking the puncturing position on the wall W.

In addition, the perforation hole forming step S120 is a step of forming a perforation hole H in the perforation position. In the step S130, the anchor 11 is installed in the perforation hole H , And the position adjusting member 12 is engaged.

The position adjustment member 12 is to be attached in order to adjust the precise position in the position adjustment step S220 of the stone panel installation step S200 to be described later.

Meanwhile, the stone panel installation step S200 may include a stone panel binding step S210, a position adjustment step S220, and a supporting means binding step S230.

The stone panel binding step S210 is a step of binding the stone panel 20 to the upper and lower portions of the position adjusting member 12. [

In addition, the position adjustment step S220 is a step of adjusting the front, rear, left and right positions of the stone panel 20 using the position adjustment member 12. [

There has been a problem in that a step difference occurs between the stone panels or the stone panel is unstably fixed when the wall W is bent or the surface is uneven. However, when the stone panel 20 is moved through the position adjusting member 12, It is possible to provide a method of constructing and reinforcing a stone that is more stable and structurally stable because it is possible to flexibly adjust the position of the stone.

The supporting means binding step S230 is a step of binding the anchor 11 of the supporting means 10 and the position adjusting member 12 together.

As shown in FIG. 2B, the stone panel 20 may be provided with a separation prevention pin 22 to prevent the separation of the foamed insulating material 30 and the stone panel 20 from each other.

The release prevention pin 22 may be manufactured in various shapes, but it is preferable that a vertical portion is formed to provide a strong adhesive force.

The anchor 11 has an elongated anchor hole 11a formed therein and the elongated position adjusting hole 12a is formed in the elongated position adjusting member 12 to adjust the position Lt; / RTI >

That is, the stone panel 20 can be moved forward and backward using the long hole-shaped position adjustment hole 12a, and can be bound to the fastening means 13 after adjusting the left and right angles.

At this time, the fastening means 13 may be formed in various ways in addition to the bolt 13a and the nut 13b as shown in FIGS. 3A and 3B.

A fixing pin 12b may be provided at an end of the position adjusting member 12 to be fixed to the fixing hole 21 formed at the upper and lower portions of the stone panel 20.

On the other hand, a vibration absorbing pad 14 is provided on the upper part of the position adjusting member 12, and a stone panel 20 can be bonded to the upper part of the vibration absorbing pad 14.

Thereby, it is possible to perform an auxiliary function for preventing the impact from being transmitted to the stone panel 20 adjacent to the upper and lower portions when an earthquake occurs or an external impact is applied.

Meanwhile, the step S300 of filling the foamed insulation material may include a step of injecting the injection device (S310) and a step of injecting the foamed insulation material (S320).

The injecting device injecting step S310 is a step of injecting the injecting device 31 including the injection port 31a and the endoscope 31b into the space S formed between the wall W and the stone panel 20 to be.

The foaming heat insulating material injecting step S320 is a step of filling the foam insulating material 30 from the lower part to the upper part of the space part S using the injection device 31. [

The foam insulator 30 can be filled with the injection unit 31 including the endoscope 31b and the injection port 31a as shown in Figure 2E so that the space S can be filled with the naked eye, This has the advantage.

Accordingly, it is possible to prevent voids that are not filled with the foamed thermal insulating material 30 during the injection process, thereby improving the heat insulating performance and the seismic performance.

At this time, it is preferable that the injection port 31a of the injection device 31 is downwardly directed so as to be filled from the lower part to the upper part.

Meanwhile, the method M of constructing and reinforcing an insulating and earthquake-resistant stone of the present invention may further comprise a wire setting step S150.

The wire installing step S150 may include a fixing member attaching step S151, a wire bonding step S152, and a wire pin attaching step S153.

The step of attaching the wire fixing member (S151) is a step of providing the wire fixing member (51) to the supporting means (10).

The wire bonding step S152 is a step of binding the wire 52 to the wire fixing member 51. [

2C, the wire fixing member 51 functions to fix the wire 52 and can be bound to the supporting means 10 in the form of a washer, Can be manufactured in various shapes.

The wire 52 can be fixed in a tensioned state by the wire fixing member 51.

Also, the step of providing a wire pin (S153) is a step of providing a wire pin (53) on the wire (52).

A wire pin 53 is provided on the wire 52 as described above so that the adhesion force between the foam insulating material 30 and the wall W is strengthened so that the separation of the foam insulating material 30 It is possible to prevent the phenomenon.

According to the heat insulating and quartz stone wall SW of the present invention, as shown in FIG. 2A, in the stone wall body SW formed with the stone panel 20 formed on the wall W formed on the inside and the outside of the building , The stone wall SW is bound to a plurality of support means 10 including the anchor 11 and the position adjustment member 12 on the wall W, And a space portion S formed between the wall W and the stone panel 20 is filled with the foamed thermal insulating material 30 so that the space between the plurality of stone panels 20 A sealing material 40 is provided and jointed.

Thus, even if the insulation standard according to the recently reinforced construction method is adopted, only the foam insulating material 30 can be filled in the space portion S, and sufficient heat insulating performance can be ensured, so that the thickness of the wall can be reduced, There is an effect.

4, the inner wall of the wall W or the stone panel 20 may be coated with an adhesion enhancer P, as shown in FIG.

2C, a wire fixing member 51 is provided on the supporting means 10, and a wire 52 is coupled to the wire fixing member 51, A wire pin 53 is provided to prevent the wall W and the foam insulating material 30 from separating from each other.

The method of constructing and reinforcing a heat insulating and earthquake-resistant stone according to the present invention is not limited to the above-described embodiments, and various modifications and changes may be made without departing from the scope of the present invention as claimed in the following claims. It should be regarded as belonging to the scope of the scope of the patent claims to the extent that any person skilled in the art can make various changes and implement them.

W: wall S:
P: Adhesion increase agent H: Perforation hole
SW: Stone wall
10: support means 11: anchor
11a: anchor hole 12: positioning member
12a: Positioning hole 12b: Fixing pin
13: fastening means 13a: bolt
13b: nut 14: vibration absorbing pad
20: Stone panel 21: Fixing hole
22: release prevention pin 30: foam insulation
31: Injection device 31a: Injection port
31b: endoscope 40: sealing material
51: wire fixing member 52: wire
53: wire pin 60: adhesive reinforcement spraying device
61: injection nozzle 62: endoscope
M: Stone construction method S100: Step of installing support means
S110: Perforation position display step S120: Perforation hole formation step
S130: Supporting means deceleration step S150: Wire installation step
S151: Step of attaching wire fixing member S152: Step of wire bonding
S153: Providing a wire pin S200: Step of installing a stone panel
S210: Stone panel binding step S220: Position adjustment step
S230: Step of binding the support means
S251: injection device injection step S252: adhesion promoter injection step
S300: Filling of foamed insulation material S310: Injection device injection step
S320: Foaming insulator injection step S400: Joint processing step

Claims (14)

A method of constructing a stone (M) for installing a stone panel (20) on a wall (W) formed on the inside and outside of the building,
The method of constructing a stone M comprises the steps of installing a supporting means (S100) for setting a plurality of supporting means (10) including an anchor (11) and a position adjusting member (12) at a predetermined position on the wall (W);
A stone panel installing step (S200) of installing a plurality of stone panels (20) on the upper and lower portions of the supporting means (10);
A foam insulating material filling step S300 of filling the space S formed between the wall W and the stone panel 20 with the foam insulating material 30; And
A joint processing step (S400) of jointing the plurality of stone panels (20) using a sealing material (40);
And applying an adhesion promoter (P) to the wall (W) or the stone panel (20)
The step of applying the adhesive strengthening agent may be performed after the step of installing the stone panel (S200) and before the step S300 of filling the foamed insulating material,
Wherein the construction of the building to be stretched is performed before the step of installing the supporting means (S100).
delete The method according to claim 1,
In the case of buildings constructed in the past,
The application of the adhesion enhancer is performed by injecting an adhesive enhancer injector 60 including an injection port 61 and an endoscope 62 into a space S formed between the wall W and the stone panel 20 A device charging step (S251); And
An adhesion enhancer injection step (S252) for injecting the adhesion enhancer (30) to the wall (W) or the stone panel (20) using the adhesion enhancer injector (60);
The method of claim 1,
The method according to claim 1,
The supporting means installation step S100 may include a drilling position display step S110 for displaying a drilling position for installing the support means 10 on the wall W;
A perforation hole forming step (S120) of forming a perforation hole (H) at the perforation position; And
A supporting step (S130) of attaching the anchor (11) to the perforation hole (H) and attaching the position adjusting member (12);
The method of claim 1,
The method according to claim 1,
The stone panel installation step S200 includes a stone panel binding step S210 binding the stone panel 20 to upper and lower portions of the position adjustment member 12;
A position adjustment step S220 of adjusting the front, rear, left and right positions of the stone panel 20 using the position adjustment member 12; And
A supporting means binding step (S230) of binding the anchor (11) of the supporting means (10) and the position adjusting member (12);
The method of claim 1,
The method according to claim 1,
The filling step S300 of filling the foam insulating material is performed by injecting an injection device 31 including an injection port 31a and an endoscope 31b into a space S formed between the wall W and the stone panel 20 Injecting device injecting step S310; And
(S320) for filling the foamed thermal insulating material (30) from the lower part to the upper part of the space part (S) using the injection device (31);
The method of claim 1,
The method according to claim 1,
The method may further include a wire installation step (S150) after the supporting means installation step (S100) and before the stone panel installation step (S200)
The wire installing step S150 includes a wire fixing member mounting step S151 of providing the wire fixing member 51 to the supporting means 10;
A wire bonding step (S152) of binding the wire (52) to the wire fixing member (51); And
(S153) a wire pin having a wire pin (53) on the wire (52);
The method of claim 1,
A stone wall (SW) formed on the inside and outside of a building,
The stone wall SW has a plurality of supporting means 10 bound to the wall W and including an anchor 11 and a position adjusting member 12, The panel 20 is bound and the space S formed between the wall W and the stone panel 20 is filled with the foamed thermal insulating material 30 and the space between the plurality of stone panels 20 Characterized in that a sealant (40) is provided and jointed, and an inner wall of the wall (W) or the stone panel (20) is coated with an adhesion enhancer (P).
delete 9. The method of claim 8,
Characterized in that the stone panel (20) is burned into a burner so that the surface area to which the adhesion enhancer (P) is applied is widened.
9. The method of claim 8,
The anchor 11 has an elongated anchor hole 11a formed therein and the elongated position adjusting hole 12a is formed in the position adjusting member 12 and its position is adjusted by the engaging means 13 , And a fixing pin (12b) is provided at an end of the position adjusting member (12) to be fixed to the fixing hole (21) formed at the upper and lower portions of the stone panel (20).
12. The method of claim 11,
Characterized in that a vibration absorbing pad (14) is provided on the upper portion of the position adjusting member (12) and a stone panel (20) is bonded to the upper part of the vibration absorbing pad (14).
9. The method of claim 8,
Wherein the stone panel (20) is provided with a separation prevention pin (22) to prevent the escape of the foamed thermal insulating material (30) and the stone panel (20).
9. The method of claim 8,
A wire fixing member 51 is provided on the supporting means 10 and a wire 52 is bonded to the wire fixing member 51. A wire pin 53 is provided on the wire 52, (W) and the foam insulating material (30) are prevented from separating from each other.

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