KR101732474B1 - constructing method of inner air venting type exterior panel assembly having spacing gap and quake proof function - Google Patents

Abstract

According to the present invention, a construction method of an inner air discharge type earthquake-proof outer wall panel assembly having a gap comprises: a support frame preparation step; an outer composite panel preparation step; a frame and panel assembly step; an outer wall installation step; a rear gasket insertion step; a waterproof caulking preparation step; and a front gasket insertion step. Therefore, according to the present invention, the present invention can provide the construction method of an inner air discharge type earthquake-proof outer wall panel assembly having a gap preventing contamination caused by a silicon caulking exposed to the outside.

Description

[0001] The present invention relates to a method of constructing an inner air venting type outer panel panel assembly having a spacing gap and an inner air venting type outer panel assembly having spacing gap and quake proof function,

The present invention relates to a method of constructing an inner air discharge type earthquake-resistant outer wall panel assembly having a spacing gap, and more particularly, To a method of constructing an inner air vent type earthquake-resistant outer wall panel assembly having a clearance so as to have a structure that is as follows.

Generally, the outer wall finishing panel is configured to constitute an outer wall or the like of a building while a plurality of finishing panels are fixedly connected to each other. That is, a single finishing panel is fastened and assembled to the fixed frame with a screw piece, and then the adjacent panels are assembled sequentially in a horizontal or vertical manner in the order of the finishing panel to finish the outer wall to complete the appearance of the building.

These exterior wall finish panels are made of stone, wood, concrete, or metal, and the back side of the panel is adhered to the outside of the fixture frame, such as styrofoam, glass fiber, or urethane, It is also equipped with a built-in thermal insulation material such as Styrofoam.

An example of the outer wall panel assembly according to the prior art is disclosed in Korean Patent Registration No. 10-1161142 (registered on June 25, 2012, hereinafter referred to as "Patent Document 1").

However, since the outer wall panel assembly according to the related art is installed in a closed type in which the joints are filled with silicone caulking when the panels are attached to the outer wall of the building, the silicone caulking is exposed to the outside and is easily contaminated. There is a problem that it can cause.

In addition, since external energy such as direct sunlight in summer and strong wind in winter is transmitted to the fixed frame without being blocked by the outer wall finishing panel, there is a problem that energy loss is greatly generated and the heat insulating effect is greatly reduced.

Particularly, when the outer wall finishing panel is made of a metal material, since the heat is transferred in the form of conduction or radiation by the inner heat insulating material, it is accumulated in the space between the outer wall finishing panel and the heat insulating material, So that the indoor temperature is greatly increased in the summer and the indoor temperature is significantly lowered in the winter. Thus, there is a problem that the heat energy efficiency may be significantly lowered.

In addition, the outer wall panel assembly according to the related art is disadvantageous in that when the outer frame is assembled with a fastening member such as a piece, an external impact such as an earthquake is applied to the outer wall panel.

Korean Patent Registration No. 10-1161142 (registered on June 25, 2012)

An object of the present invention is to provide a structure in which a joint is opened without providing a silicon caulking for covering joints when the panels are attached to the outer wall of a building so as to prevent the contamination by the silicon caulking exposed to the outside, To provide a method of constructing an inner air discharge type seismic outer wall panel assembly.

Also, there is a method of constructing an inner air exhaust type seismic outer panel assembly having a gap which can open the joint and allow the air inside the space between the finishing panel and the heat insulation to be discharged to the outside, .

The present invention also provides a method of constructing an inner air discharge type earthquake-resistant external wall panel assembly having a clearance that can prevent the panel assembly from being damaged by securing seismic performance by reducing left-right rocking vibration even when an external impact such as an earthquake is applied .

In order to accomplish the above object, there is provided a method of constructing an inner air discharge type earthquake-resistant outer panel panel assembly having a spacing clearance according to the present invention, comprising the steps of: forming a quadrangular shape in which drainage passages are formed on outer side surfaces in four directions, Preparing a support frame on the inside and outside of the adjoining rear portion of the portion where the air bearing holes are formed, the air bearing holes communicating with each other through the air transfer passages formed in the support frame so as to be offset from each other; An outer composite panel preparation step of preparing an outer composite panel which is tightly fixed to the front of the support frame and finishes the exterior of the building; A frame and a panel assembling step of fastening and fixing the outer composite panel in a corresponding manner in front of the support frame; An outer wall installing step of installing the assembled support frame and a plurality of outer composite panels on outer walls of the building so as to have mutually spaced gaps in a plane; A rear gasket insertion step of inserting a rear gasket made of an elastic material having a plurality of vent holes formed on the side surface thereof between the spaced gaps, A waterproof caulking step of providing a waterproof silicone caulking on a front outside of the rear gasket; And a front gasket of an elastic material formed with a plurality of ventilation holes on the side surface in front of the waterproof silicone caulking is inserted so that an open portion between drainage passages of a pair of the support frames, And a front gasket fitting step for intercepting the front gasket.

A method of constructing an inner air discharge type earthquake-resistant outer panel panel assembly having a spacing gap according to the present invention includes the steps of: A step of preparing a sliding fastening bracket for preparing a sliding fastening bracket to be inserted into a rear inner side of the supporting frame so as to be slidable; and a step of preparing a sliding fastening bracket, wherein a plurality of the sliding fastening brackets, And a sliding fastening bracket assembling step of inserting the sliding fastening bracket into the rear inner side of the receiving frame.

A method of constructing an inner air discharge type earthquake-resistant outer wall panel assembly having a spacing gap according to the present invention is characterized in that it is provided between the step of preparing the sliding fastening bracket and the step of assembling the sliding fastening bracket, The heat shield plate preparing step of preparing the heat shield plate and the heat shield plate assembling step of coupling the heat shield plate to the inner rear side of the receiving frame.

In addition, in the step of preparing the support frame, the air discharge hole may be defined by a water blocking wall protruding from the inside of the support frame so that the air movement passage forms an 'a' 'shaped path.

According to the present invention, it is possible to provide a structure in which the joints are opened without the silicone caulking filling the joints when the panels are attached to the outer wall of the building, so that a gap, which can prevent contamination by the silicon caulking exposed to the outside, The present invention can provide a method of constructing an inner air exhaust type earthquake-resistant outer wall panel assembly.

Further, it is possible to provide a ventilation passage inside the supporting frame so that the joint is opened and the air inside the space between the finishing panel and the heat insulating member is discharged to the outside, thereby having a gap for allowing the heat energy efficiency to be improved by effective heat blocking It is possible to provide a method of constructing an inner air exhaust type seismic outer wall panel assembly.

In addition, even if an external shock such as an earthquake is applied, the sliding fastening brackets reduce the left-right shaking vibration to secure the seismic performance, thereby preventing the panel assembly from being damaged. Method can be provided.

1 is a process flow diagram for explaining a method of constructing an inner air discharge type seismic outer wall panel assembly having a spacing gap according to the present invention,
FIG. 2 is a process flow chart for explaining a more specific construction method of FIG. 1,
FIG. 3 is a perspective view showing a single combined assembly of an outer composite panel in front of one support frame to be installed according to a method of constructing an inner air vent type earthquake-resistant outer panel assembly having a spacing gap according to the present invention;
Fig. 4 is a side sectional view of the support frame and the outer composite panel of Fig. 3,
Fig. 5 is a side cross-sectional view of the support frame and the sliding fastening bracket of Fig. 4,
6 is an enlarged side sectional view of the sliding fastening bracket of Fig. 5, Fig.
FIG. 7 is a front view of an inner air discharge type earthquake-resistant external wall panel assembly having a spacing gap constructed according to a construction method according to the present invention,
8 is an enlarged side sectional view of the " A "

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, a method of constructing an inner air discharge type earthquake-resistant outer wall panel assembly having a spacing gap according to the present invention includes a support frame preparation step (S10), an outer composite panel preparation step (S20) The assembling step S30, the outer wall installing step S40, the rear gasket fitting step S50, the waterproof caulking preparing step S60, and the front gasket fitting step S70.

As shown in FIGS. 3 and 5, the supporting frame preparing step S10 is a step of forming a supporting frame 110 in a rectangular shape and having a drainage hole 110 formed on the outer side in four directions, (130) which are communicated with each other through air moving passages (120) formed inside the support frame (100) at the inside and outside of the adjoining rear portion of the support frame do.

5, in the step 10, the air discharge hole 130 is formed in the inside of the support frame 100 so that the air transfer passage 120 forms an ' It is preferable that the partition wall is formed by the water blocking wall 150 protruding from the partition wall 150.

Accordingly, when the water is discharged through the drainage passage 110, water can be prevented from entering the air discharge hole 130 by the water blocking wall 150, and water can be impregnated into the air discharge hole 130 So that it can be blocked by the water blocking wall 150 and prevented from entering the air movement passage 120.

As shown in FIGS. 3 and 4, the external composite panel preparing step S20 includes the steps of preparing an external composite panel 200 (see FIG. 3), which is tightly fastened to the front of the support frame 100 prepared in step 10, ). ≪ / RTI >

As shown in FIGS. 3 to 5, the frame and panel assembling step S30 is a step of assembling the outer composite panel 200 prepared in step 20 correspondingly to the front of the support frame 100 prepared in step 10, .

More specifically, step 30 includes a step of recessing the sealant filling part 140 to fill the structural sealant 400 at the front both ends of the support frame 100 to which the external composite panel 200 is coupled, Filling the sealant filling part 140 with the structural sealant 400 and disposing the outer composite panel 200 in front of the support frame 100; 200) to the fastening member (300).

The outer wall installation step S40 includes a step of installing a plurality of sets of the support frame 100 assembled in the step 30 and the outer composite panel 200 on the outer wall of the building so as to have a mutually spaced clearance 10 .

The rear gasket fitting step S50 includes a step of inserting a plurality of ventilation holes 20 on the side surface between the supporting frame 100 installed on the outer wall of the building and the gaps 10 spaced apart from the plurality of tanks of the outer composite panel 200, And inserting the rear gasket 500 of an elastic material formed therebetween.

The waterproof caulking step S60 includes the step of providing a waterproof silicone caulking 700 on the outside of the front side of the rear gasket 500 interposed between the spacing gaps 10 in step 50. [

The front gasket fitting step S70 is performed by inserting a front gasket 600 made of an elastic material having a plurality of vent holes 20 formed on the side surface thereof in front of the waterproof silicone caulking 700 provided in the step 60, ) Of the pair of support frames (100) spaced apart from each other by the front side of the drainage passages (110).

Accordingly, when a plurality of troughs of the support frame 100 and the outer composite panel 200 are installed on the outer wall of the building, the spacing gap 10 is opened without silicon caulking filling the gaps 10 that are spaced apart from each other The present invention can provide a method of constructing an inner air exhaust type seismic outer wall panel assembly having a spacing gap that can prevent contamination due to silicon caulking exposed to the outside.

As shown in FIG. 2, between the outer composite panel preparing step S20 and the frame and panel assembling step S30, the length of the supporting frame 100 in the four directions of the supporting frame 100 A sliding fastening bracket preparation step S21 for preparing a sliding fastening bracket 800 to be inserted into the rear inner side of the support frame 100 so as to be slidable in the direction of the sliding fastening brackets 800, And a sliding fastening bracket assembling step (S27) for inserting the sliding fastening brackets (800) into the rear inside of the receiving frame (100) so as to correspond to each of four side faces of the frame (100).

Accordingly, even when an external shock such as an earthquake is applied, the sliding fastening bracket 800 can reduce the left-right shaking vibration to secure the seismic performance, thereby preventing the panel assembly from being broken, A method of constructing the panel assembly can be provided.

More specifically, as shown in FIGS. 4 and 8, between the step of preparing the sliding fastening bracket S21 and the step of assembling the sliding fastening bracket S27, The heat shield plate assembly step S23 for preparing the heat shield plate 900 provided in the step 23 and the heat shield plate assembly step for joining the heat shield plate 900 prepared in the step 23 to the inner rear side of the support frame 100 (S25).

Accordingly, the heat accumulated in the space between the external composite panel 200 and the heat insulating material through the internal air can be more reliably blocked by the heat shielding plate 900.

Meanwhile, as shown in FIGS. 3 and 8, the inner air vent type earthquake-resistant outer panel panel assembly having a spacing gap constructed by the construction method according to the present invention has a square shape, A support frame 100 having a drainage path 110 embedded in the side surface thereof and an external composite panel 200 fastened and fixed to the front of the support frame 100 to close the exterior of the building, Are installed on the outer wall of the building.

Accordingly, one of the supporting frames 100 and the external composite panel 200 constituting one set are separated from the other supporting frame 100 and the external composite panel 200, Even if it is installed in such a structure that the clearance 10 is opened without the silicon caulking which fills the joint with the direct exposure type, water such as rainwater or condensation is later introduced into the outer composite panel 10 through the drainage passage 110, So that the water is discharged from the inside of the outer composite panel 200 neatly.

As shown in Figs. 3 to 5, the support frame 100 is made of an aluminum material. The support frame 100 is formed of, for example, an aluminum material. In the inside and outside of the adjoining rear portion of the portion where the drainage passage 110 is recessed, The air discharge holes 130 communicating with each other through the air transfer passage 120 formed inside the discharge port 100 are staggered from each other and a pair of rivets The rear of the outer composite panel 200 is tightly fixed to the outer composite panel 200 through the same fastening member 300 and the front and rear ends of the outer composite panel 200, The sealant filling part 140 is recessed so that the same structural sealant 400 is filled.

The ventilation gap 130 is opened by the ventilation gap 130 and the air passage 120 is formed in the inside of the support frame 100 so that the air in the space between the panel and the heat insulating material can be easily discharged to the outside. The heat accumulation by the internal air can be reduced and the thermal energy efficiency can be improved by effectively dissipating the heat generated by the external composite panel 200 and the support frame 100, The structural sealant 400 is provided on the support frame 300 so that the structural sealant 400 is compressed when the external composite panel 200 is coupled to the support frame 100 by the fastening member 300, The airtightness due to the double contact can be ensured together with the airtight container 300.

5, the air discharge hole 130 is formed in the inside of the support frame 100 so that the air transfer passage 120 is formed in a substantially ' It is preferable that the partition wall is formed by the water blocking wall 150 protruding from the partition wall 150.

Accordingly, the air transfer passages 120 are formed in a substantially 'r' shape and the air exhaust holes 130 are formed to be offset from each other in the vertical and horizontal directions on the inner and outer sides of the support frame 100, The heat dissipation effect can be increased while the internal air is discharged to the outside, and the heat shielding effect can be further increased by the water blocking wall 150 performing the function of the heat transfer fins, Water can be prevented from entering the air discharge hole 130 by the water blocking wall 150 when water is discharged through the air discharge hole 130 and water can be prevented from entering the water discharge wall 130 even if water is permeated into the air discharge hole 130. [ Thereby preventing the air passage 120 from being blocked.

5 and 8, at an inner end portion of the support frame 100 facing the central portion of the outer composite panel 200 at the front portion where the sealant filling portion 140 is formed, The front inner protrusion 160 is protruded from the outer composite panel 200 at a distance of about 0.5 mm to 1 mm and the rear inner surface of the outer composite panel 200 and the front inner surface of the outer composite panel 200 So that the structural sealant 400 is filled between the protrusions 160.

The sealant 400 is filled in the sealant filling part 140 and the outer composite panel 200 is joined to the front of the support frame 100 by the fastening member 300. Thereafter, When the silicone sealant 400 is applied to fill the gap between the support frame 100 and the external composite panel 200, the sealant can be more reliably secured by the triple adhesion.

As shown in FIGS. 3 and 4, the outer composite panel 200 has a honeycomb structure of a metal material such as aluminum and has a thickness of about 4 mm to 10 mm. That is, the outer composite panel 200 is provided with an outer steel plate, and a plurality of metal plates are provided inside the inner composite panel 200 to form core members having a substantially hexagonal honeycomb structure in a lattice form or zigzag form, And an inner steel plate is provided at the rear.

7 and 8, an inner air exhaust type earthquake-resistant outer panel assembly having a spacing gap according to the present invention is a structure in which the outer composite panel 200 and the support frame 100 form a single Any one of the outer composite panel 200 and the support frame 100 may be separated from the other outer composite panel 200 and the support frame 100 by a gap 10 spaced apart from each other. Respectively.

As shown in FIG. 8, the spaced-apart clearance 10 includes a rear gasket 500 of an elastic material such as rubber or silicone having a plurality of ventilation holes 20 formed on a side surface thereof, And a waterproof silicone caulking 700 between the rear gasket 500 and the front gasket 600 is formed in a non-visible manner .

For this purpose, as shown in FIGS. 5 and 8, a front portion of the drainage duct 110 is bent and bent rearward so that the front catching jaw of the front gasket 600 is coupled to the receiving frame 100, It is preferable that the protrusions 170 are formed so as to protrude toward the mutually facing support frame 100 which are mutually opposed to each other.

Thus, by providing the structure in which the spacing gap 10 is simply opened without the silicon caulking that directly fills the spacing gap 10 with the external exposing type, contamination by the silicon caulking that is exposed to the outside can be originally prevented .

8, a vent hole 20 is formed at the center of the side section on the side section, and a plurality of vent holes 20 are formed on both sides of the vent hole to vertically define the airtightness between the spacing gaps 10 So that the water introduced from the outside is prevented from penetrating between the panel assembly and the outer wall of the building according to the present invention.

8, a vent hole 20 is formed in the middle center of a side cross section, and a plurality of vent holes 20 are formed at upper and lower sides of the front gasket 600, And the air gap between the panel and the heat insulating material is discharged to the outside by allowing water flowing from the outside to be firstly waterproofed before the water penetrates into the rear gasket (500) .

8, the waterproof silicone caulking 700 is formed by applying silicone to the front outer surface of the rear gasket 500 so as to be formed between the front gasket 600 and the front gasket 600, So as to perform a waterproof function to prevent water from penetrating between the support frame 100 and the rear gasket 500 and the front gasket 600.

It is preferable that the front outer side of the front gasket 600 according to the present invention is provided for finishing the open portion between the drainage passages 110 of the pair of receiving frames 100 spaced apart from each other.

Accordingly, it is possible to provide an open type structure in which the clearance 10 of the panel assembly according to the present invention is opened without silicon caulking which is exposed to the outside.

3 to 5, the inner air venting type earthquake-resistant outer panel assembly having the spacing gap according to the present invention includes a support frame 100 so as to be slidable in the longitudinal direction from four sides of the support frame 100, And a plurality of sliding fastening brackets 800 that are inserted into the rear inner side of the building and fastened and fixed to the outer wall of the building to support the support frame 100 to be fixed to the outer wall of the building.

For this, as shown in FIGS. 5 and 8, it is preferable that the sliding rail groove 180 is recessed to guide the sliding movement of the sliding fastening bracket 800 to the rear side of the support frame 100.

Accordingly, even when an external shock such as an earthquake is applied, the sliding fastening bracket 800 can reduce the left and right shaking vibrations by sliding in the up, down, left, and right directions to secure the seismic performance, thereby preventing the panel assembly according to the present invention from being damaged have.

5 and 6, the sliding fastening bracket 800 is made of a metal material such as aluminum to which elasticity is imparted, and the diameter of the end portion of the sliding fastening bracket 800 is increased so as not to be separated from the sliding rail groove 180 A sliding rail portion 810 which is hooked to the inside of the sliding rail groove 180 and inserted in the sliding rail groove 180 to slide along the sliding rail groove 180, And a fastening plate 830 extending from the bent portion 820 toward the outer side of the receiving frame 100 and fastened to a lower section steel member installed on the outer wall of the building.

4 and 8, an inner air exhaust type earthquake-resistant outer panel assembly having a spacing gap according to the present invention includes an electric heat shielding plate 900, which is disposed to block a rear portion from the inside of the support frame 100, As shown in FIG.

The heat shield plate 900 is provided as an insulating material so as to block or reflect the heat accumulated and diffused through the air inside the space between the panel and the heat insulating material.

5, a heat blocking protrusion (not shown) is formed on the front side of the sliding rail groove 180 on the inner rear side of the supporting frame 100 so that the heat blocking plate 900 is coupled to the inside of the supporting frame 100 190 are protruded and formed.

Accordingly, as shown in FIG. 8, heat transmitted to the external composite panel 200 through the air inside the space between the panel and the heat insulating material is blocked by the heat shielding plate 900, The effect of improving the thermal energy efficiency by the panel assembly according to the present invention can be further increased together with the discharge hole 130 and the air transfer passage 120.

While the invention has been described in connection with what is presently considered to be practical exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims.

100: Support frame 110: Drain
120: air transfer passage 130: air discharge hole
150: Water blocking wall 200: External composite panel
500: rear gasket 600: front gasket
700: Waterproof silicone caulking 800: Sliding fastening bracket
900: Heat shield plate

Claims (4)

And a drainage passage is formed in an outer side surface in four directions. The inner and outer sides of the adjoining rear portion of the portion where the drainage passage is formed on four sides are mutually communicated through the air passage formed inside the receiving frame A support frame preparation step of preparing a support frame formed with air discharge holes staggered from each other;
An outer composite panel preparation step of preparing an outer composite panel which is tightly fixed to the front of the support frame and finishes the exterior of the building;
A frame and a panel assembling step of fastening and fixing the outer composite panel in a corresponding manner in front of the support frame;
An outer wall installing step of installing the assembled support frame and a plurality of outer composite panels on outer walls of the building so as to have mutually spaced gaps in a plane;
A rear gasket insertion step of inserting a rear gasket made of an elastic material having a plurality of vent holes formed on the side surface thereof between the spaced gaps,
A waterproof caulking step of providing a waterproof silicone caulking on a front outside of the rear gasket; And
Wherein a front gasket of an elastic material having a plurality of ventilation holes formed on a side surface thereof is inserted in front of the waterproof silicone caulking so as to close an open portion between drainage passages of a pair of the above- A front gasket fitting step for allowing the gasket to be processed;
Wherein the inner wall of the inner wall of the inner wall of the inner wall of the inner wall of the inner wall of the inner wall of the inner wall of the inner wall of the inner wall of the inner wall is formed. The method according to claim 1,
Between the external composite panel preparing step and the frame and panel assembling step,
A sliding fastening bracket preparing step of preparing a sliding fastening bracket to be inserted into a rear inner side of the support frame so as to be slidable in the longitudinal direction from four side faces of the support frame,
Further comprising a sliding fastening bracket assembling step of inserting the sliding fastening brackets into the rear inside of the receiving frame so that a plurality of the sliding fastening brackets correspond to each one of the four side faces of the receiving frame. Wherein the inner wall of the inner wall of the outer wall panel has an inner surface. 3. The method of claim 2,
Between the step of preparing the sliding fastening bracket and the step of assembling the sliding fastening bracket,
A heat blocking plate preparing step of preparing an heat blocking plate provided so as to block the inner side to the rear side of the supporting frame,
Further comprising a heat shield plate assembling step of joining the heat shield plate to an inner rear of the support frame. ≪ Desc / Clms Page number 19 > 4. The method according to any one of claims 1 to 3,
Wherein the air discharge hole is defined by the water blocking wall protruding from the inside of the receiving frame so that the air moving passage forms an ' A method of constructing an exhaust type seismic outer wall panel assembly.

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