KR20130014778A - Panel and finishing type of external insulation structures - Google Patents

Abstract

PURPOSE: A panel finishing type outer insulation structure is provided to facilitate the easy, convenient and durable finish work for the exterior wall of a building installed with a insulation material. CONSTITUTION: A panel finishing type outer insulation structure includes an anchor bolt, a leveling plate(100), a first channel bar(300), a second channel bar(400), and a fixing piece(700). The anchor bolt has one side fixed on a concrete underground layer(10) and the other side installed to penetrate an insulation material(20) to fix the insulation material onto the concrete underground layer. The leveling control plate forms a vertical plate fixed with tight contact to the insulation layer by being connected to the other side of an anchor bolt and a horizontal plate connected with the upper end of the vertical plate. The first channel bar has both ends of the one open side coupled with the horizontal plate toward a finishing panel(500) and multiple coupling projections formed on both ends. The second channel bar has both ends of one open side coupled with the coupling projections to be interlocked, and the other closed side coupled with the finishing panel. The fixing piece is connected to the finishing panel and the second channel bar by a penetration or to the finishing panel by the penetration of the second and the first channel bar.

Description

PANEL AND FINISHING TYPE OF EXTERNAL INSULATION STRUCTURES}

The present invention is to a panel finish type outer insulation structure for binding the finishing panel in which the insulation and the paint finish is bonded to the building concrete base surface.

The present invention relates to an outer wall insulation structure of a building including a multi-family house. In particular, the present invention relates to an outer insulation structure for installing an insulation on the outer wall of a building for high-quality apartments and efficient use of energy, and relates to an outer insulation structure for improving the insulation effect of buildings and the finishing performance of building construction. .

In the past, a heat-insulating structure for installing a heat insulating material on an inner wall of a building for heat insulation of a building has been generally used.

However, the heat-insulating method for constructing the heat insulating material on the inner wall has a problem in that mold, condensation, and heat insulation effect are remarkably inferior due to discontinuity caused by the construction of the heat insulating material on the wall and the bottom surface. In this case, a heat bridge refers to a phenomenon in which a part of the wall becomes thinner due to its structure or condensation occurs when a part having a small heat permeation resistance different from a material occurs.

In order to solve such a problem, research on the outer insulation structure is being conducted, and most of the outer insulation structures until now are mainly used a wet method called a dry bit.

1 is a view showing the configuration of a conventional outer insulation structure.

However, this wet method has a problem that the impact and durability problems due to the construction of the wet mortar finish.

In addition, by using an organic insulating material as a heat insulating material, a thermal bridge phenomenon due to fire spreading, shrinkage of the heat insulating material is generated, and thus there is a problem that the durability is further lowered.

The panel finish outer insulation structure of the present invention is derived to solve the problems of the prior art has the following object.

First, it is possible to adjust the position of the finishing panel to which the coating finish is attached while fixing the insulation to the outer surface (hereinafter referred to as 'concrete lower surface') of the concrete structure that forms the outer wall of the building in the vertical direction. Do it.

Secondly, the second channel-bar coupled to the wall end panel can be easily and simply attached to and detached from the first channel-bar.

Third, by presenting a structure that the insulation and the outside is isolated by the insulation track, to prevent external exposure and moisture penetration of the insulation.

Fourth, it is intended to provide an outer insulation structure that the heat insulating material can be firmly bonded to the concrete base surface.

Fifth, to provide an installation structure of the inorganic insulating material is installed on the concrete base surface instead of the organic insulating material.

The solution to the problem of the present invention is not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

Panel finish type outer heat insulating structure according to the present invention is fixed on one side of the concrete base surface 10 and the other side is installed to penetrate the heat insulating material 20 to anchor the heat insulating material 20 to the concrete base surface 10 Bolt 200; Leveling control plate 100 is fastened to the other side of the anchor bolt 200 to form a vertical plate 110 which is tightly fixed to the heat insulating material 20 and a horizontal plate 120 connected to the upper portion of the vertical plate 110 by a horizontal plate. ); In the form of a channel-bar, both ends of the open side are fastened on the horizontal plate 120 to face the finishing panel 500 and a plurality of coupling protrusions 330 are formed on both sides of the open side. First channel-bar 300; And a second channel-bar 400 having a channel-bar shape, in which both ends of one side of the open side are engaged with the coupling protrusion 330 and the finishing panel is coupled to the other closed side. It includes.

The panel-finished outer insulation structure further includes a fixing piece 700 fastened through the finish panel and the second channel-bar or fastened through the finish panel and the second channel-bar and the first channel-bar. Characterized in that.

The vertical plate 110 has an elongated horizontal plate leveling hole 111 is formed, and the other side of the anchor bolt 200 is fitted into the horizontal plate leveling hole 111 to be fastened, thereby providing a leveling control plate 100. The position can be adjusted in the vertical direction (YY 'direction).

Longitudinal front and rear leveling holes 121 are formed in the horizontal plate 120,

The first channel-bar 300 forms a square pipe shape in which one side is opened by forming a support plate 310 and a bending plate 320 that are bent from both end portions of the support plate, and the front and rear leveling holes 121 are formed. ) And the horizontal plate 120 and the bending plate 320 are fastened by the fastening bolt 600 penetrating through the bending plate 320 to adjust the position of the first channel-bar 300 to the horizontal plate ( 120 may be adjusted in the front-rear direction (XX 'direction).

The bending plate 320 has an elongated left and right leveling hole 321, and the bending plate 320 is fastened to the fastening bolt 600 passing through the left and right leveling holes 321 and the front and rear leveling holes 121. By being fastened to the horizontal plate 120, the position of the first channel-bar 300 can be adjusted on the horizontal plate 120 in the left-right direction (ZZ 'direction) simultaneously with the front-back direction. do.

The coupling protrusion 330 is formed with protrusions 331 extending from both end portions thereof, and thus, recesses 332 inwardly formed on both sides of the coupling protrusion 330 are formed, and the second channel-bar ( 400 is characterized in that both ends of the open side is inserted into the fastening recess 332 and engaged with the coupling protrusion 330 to be coupled to the first channel-bar 300.

The second channel-bar 400 forms an opposing plate 410 facing the finishing panel 500 and a clip plate 420 bent from both ends of the opposing plate, and the clip plate 420 is It is characterized in that coupled to the engagement between the engaging projection (330).

The counter plate 410 is formed with an uneven portion 411 along the center line in the longitudinal direction of the counter plate, a coupling hole 412 is formed in the center of the uneven portion 411, the finishing panel and the coupling hole It is characterized in that it further comprises a fixing piece 700 is fastened through or fastened through the closing panel and the coupling hole and the first channel-bar.

The clip plate 420 is further formed with a locking portion 430 has an end bent inward, and the coupling protrusion 330 has a protrusion 331 extending from both side ends to protrude. A fastening recessed part 332 which is inwardly formed on the side is formed, and the locking part 430 is inserted into the fastening recessed part 332 so that the clip plate 420 is coupled to engage the engaging protrusion 330. It features.

The locking portion 430 is characterized in that it is formed to be upward toward the opposite plate 410.

The locking portion 430 is upwardly formed to have a predetermined inclination angle θ toward the opposing plate 410, and the inclination angle θ is upwardly 10 degrees based on a imaginary line connecting both ends of the clip plate. Characterized in that it is formed to have a value of 25 degrees.

The locking portion 430 is characterized in that the protrusion 431 is formed extending from the end to the upper side.

Under the heat insulating material 20 and the finishing panel 500, one side forms a heat insulating material contact plate 820 is in close contact with the heat insulating material and the other side is a closing panel contact plate 830 in close contact with the finish panel. It characterized in that it further comprises an insulation track 800 consisting of a connecting plate 810 connecting the insulation contact plate and the closing panel contact plate.

The heat insulator is a non-shrinkable non-flammable inorganic heat insulator, characterized in that consisting of a glass wool (Glass-Wool), mineral wool (Mineral-Wool) and aluminosilicate (Alumina-Silicate).

Panel finish type external insulation structure according to the present invention has the following effects.

First, by providing a structure that can be fixed and coupled the insulation to the concrete base surface and at the same time to control the position of the finishing panel to be combined with the paint finish in the vertical direction, front and rear or left and right, it is easy and convenient to finish the exterior wall of the building where the insulation is installed It has the effect of providing a panel-finished outer insulation structure that can be firmly constructed.

Second, by configuring the binding and disassembly of the first channel-bar and the second channel-bar to enable the clip method to simplify the finishing construction, there is an effect to shorten the air (work) and reduce the construction cost.

Third, by minimizing the thermal bridge phenomena due to the shrinkage change of the insulation by installing an insulation track at the bottom of the insulation to block the contact between the insulation and the outside, there is an effect of suppressing the occurrence of condensation, mold and deterioration of the building.

Fourth, by providing an outer insulation structure for bonding the insulation to the concrete base surface, it is possible to increase the internal air insulation effect of the building to significantly reduce the energy of the building.

Fifth, by providing an outer insulation structure including a panel finish to install the inorganic insulation on the concrete base surface, eliminating the risk of shrinkage change and fire spread of the insulation, and excellent workability and durability, finish and economic efficiency.

The effects of the present invention are not limited to those mentioned above, and other solutions not mentioned may be clearly understood by those skilled in the art from the following description.

1 is a block diagram of an outer insulation structure according to the prior art.
Figure 2 is a side cross-sectional view of a panel finished outer insulation structure according to the present invention.
3 is an enlarged view of a portion 'A' shown in FIG. 2.
4 is a perspective view of the leveling adjustment plate.
5 is a perspective view of a combination of the anchor bolt and the insulation and the leveling control plate.
Figure 6 is a side cross-sectional view showing a coupling configuration of the concrete base surface and the heat insulating material and the anchor bolt and leveling control plate.
7 is a conceptual diagram for illustrating a coupling configuration of an insulation track.
8 is a side cross-sectional view for illustrating the coupling configuration from the leveling control plate to the finish panel.
9 is a conceptual diagram illustrating a coupling relationship between a leveling control plate and a first channel-bar.
10 is a front view of the first channel-bar.
11 is a front view of the second channel-bar.
12 is a front view for illustrating a coupling configuration of the first channel and the second channel.
FIG. 13 is a front sectional view for illustrating a coupling configuration of a first channel-bar and a second channel-bar, a finish panel, and a paint finish. FIG.
14 is an explanatory diagram for explaining a coupling method of a first channel-bar and a second channel-bar.

Hereinafter, with reference to the accompanying drawings for the panel-finished outer insulation structure according to the present invention will be described in detail.

The present invention relates to a structure that combines the insulating material 20 and the paint finish 30 constituting the outermost surface of the building to a concrete structure (that is, concrete outer wall) of the building forming the exoskeleton of the building, in particular of the concrete structure It relates to an outer insulation structure for bonding the heat insulating material to the outer surface of the concrete base surface.

2 is a view showing the overall configuration of the panel-finished outer insulation structure according to a preferred embodiment of the present invention, Figure 3 is an enlarged view 'A' portion shown in FIG.

As shown in FIGS. 2 and 3, the panel-finished outer insulation structure according to the present invention includes a leveling control plate 100, an anchor bolt 200, a first channel-bar 300, and a second channel-bar 400. And the like.

At this time, the anchor bolt 200 has one side fixed to the concrete base surface 10 and the other side penetrating the heat insulating material 20 in close contact with the concrete base surface 10 to protrude outside the heat insulating material 20. It is installed as possible. That is, the heat insulating material 20 is fixed to the concrete base surface 10 by the anchor bolt 200.

The leveling control plate 100 is composed of a vertical plate 110 and a horizontal plate 120 (see Fig. 4).

The vertical plate 110 is fastened to the other side of the anchor bolt 200 is fixed in close contact with the heat insulating material 20, the horizontal plate 120 is formed to be connected to the horizontal plate from the upper end of the vertical plate (110). do.

At this time, the leveling control plate 100 is tightly fixed to the heat insulator 20 by fastening the nuts N to both sides of the anchor bolt 200 based on the vertical plate 110 (see FIG. 6).

The first channel-bar 300 is in the form of a channel-bar. At this time, the channel-bar (Channel-Bar) refers to a bar (Bar) of the approximately Di-shaped ('' ') shape is open on one side or a square pipe shape is open on one side (the same).

The first channel-bar 300 having a channel-bar shape is fastened to be fixed on the horizontal plate 120 of the leveling control plate 100. At this time, both ends of the open side of the first channel-bar 300 are disposed to face the finishing panel 500 which is disposed to face the heat insulating material 20.

A plurality of coupling protrusions 330 (see FIGS. 9 and 11) are formed along the length direction of the first channel-bar 300 at both ends of the open side of the first channel-bar 300.

The second channel-bar 400 is in the form of a channel-bar with one side open. In this case, the shape of the channel-bar is as described above.

One open side of the second channel-bar 400 is engaged to engage with the coupling protrusion 330, so that the second channel-bar 400 and the first channel-bar 300 cross each other. . In this case, the second channel-bar 400 and the first channel-bar 300 are preferably fastened to be perpendicular to each other.

That is, the second channel-bar 400 is coupled to the first channel-bar 300 such that the other closed side is toward the finish panel 20 side. At this time, the closing panel 500 is coupled to the other closed side of the second channel-bar 400.

In this case, the finishing panel 500 may be fastened and fixed to the other sealed side of the first channel-bar 300 by the fixing piece 700. That is, the fixing piece 700 together with the finish panel 500 and the second channel-bar 400 or with the finish panel 500 and the second channel-bar 400 and the first channel-bar 300 By fastening together), the finishing panel 500 is coupled to the other closed side of the second channel-bar 400.

Hereinafter, each component and the coupling relationship between the components will be described in more detail.

4 is a diagram illustrating a configuration of the leveling adjustment plate 100.

As shown in FIG. 4, the leveling control plate 100 is divided into a vertical plate 110 and a horizontal plate 120.

That is, the leveling control plate 100 has a vertical plate 110 and the vertical plate 110 fastened to the anchor bolt 200 to be in contact with the outer surface of the heat insulating material 20 in the form of a tracer ('ㄱ'). It consists of a horizontal plate 120 extending from the horizontal plate.

In the vertical plate 110, an elongated horizontal plate leveling hole 111 may be formed in the longitudinal direction (Y-Y 'direction shown in FIG. 8) of the vertical plate 110.

At this time, the other side of the anchor bolt 200 protruding through the heat insulating material 20 is fitted into the horizontal plate leveling hole 111 and fastened.

An elongated front and rear leveling hole 121 may be formed in the horizontal plate 120 in the longitudinal direction (X-X 'direction shown in FIG. 8) of the horizontal plate 120.

In this case, only one or both of the horizontal plate leveling hole 111 and the front and rear leveling holes 121 may be formed together, and the horizontal plate leveling hole 111 and the front and rear leveling holes 121 together. If formed, they may be formed as holes connected to each other, or may be formed as separate holes, respectively. In this case, when only the horizontal plate leveling hole 111 is formed, only a vertical position (YY 'direction, see FIG. 8) of the leveling control plate 100 may be adjusted, and thus only the vertical position of the leveling control plate 100 may be adjusted. As described later, the horizontal plate leveling hole may be adjusted together with the position of the front and rear directions (XX 'direction, see FIG. 8) of the first channel-bar 300 fastened on the horizontal plate 120. It is preferable that the 111 and the front and rear leveling holes 121 are formed together. The fastening structure of the horizontal plate 120 and the first channel-bar 300 will be described later.

FIG. 5 is a view illustrating a configuration in which the other side of the anchor bolt 200 is fitted into the horizontal plate leveling hole 111 formed in the vertical plate 110.

As shown in FIG. 5, the leveling control plate 100 is moved in a horizontal plate, that is, in an up-down direction (YY 'direction, see FIG. 8) by the horizontal plate leveling hole 111 into which the other side of the anchor bolt 200 is fitted. By enabling this, it is possible to adjust the vertical position of the leveling adjustment plate 100.

That is, by adjusting the position of the horizontal plate leveling hole 111 into which the anchor bolt 200 is fitted, the correct upper and lower positions of the leveling control plate 100 are set, and the anchor inserted into the horizontal plate leveling hole 111. By fastening the nut N to the other side of the bolt 200, the leveling control plate 100 may be fixedly coupled to the heat insulating material 20 and the concrete base surface 10.

6 is a view showing the configuration of the leveling control plate 100 fixedly coupled to the concrete base surface 10 and the heat insulating material 20.

As shown in FIG. 6, nuts (N, Nut) are fastened to both sides of the vertical plate 110 on the other side of the anchor bolt 200 fitted in the horizontal plate leveling hole 111. At this time, the washer (W, Washer) is preferably inserted between the vertical plate 110 and the nut (N). The washer W may prevent the nut N or the leveling control plate 100 from rotating.

FIG. 7 is a diagram illustrating a configuration in which the insulation track 800 is installed below the insulation 20.

As shown in FIG. 7, the heat insulating material track 800 is connected to the connecting plate 810 and a horizontal plate from one end of the connecting plate 810 by a horizontal plate and the other side of the connecting plate 810. A finish contact plate 830 connected from the end to the transverse plate.

The heat insulating material contact plate 820 is coupled to be in close contact with the bottom inner surface, preferably the bottom end outer surface of the heat insulating material 20, the finish contact plate 830 is a closing panel disposed to face the heat insulating material 20 ( By being coupled to be in close contact with the inner side of the lower end of the 500, preferably the innermost end, it is possible to prevent the moisture from rising through the empty space between the heat insulating material 20 and the finishing panel 500.

In this case, the heat insulating material contact plate 820 and the finish contact plate 830 may be coupled to the heat insulating material 20 or the finishing panel 500 by the fixing pin 900, respectively.

The insulation track 800 may prevent the insulation 20 from sagging due to external exposure for a long time or moisture infiltration into the insulation 20.

At this time, the heat insulating material track 800 and the insulating panel 20 and the finishing panel in a range that does not overlap the configuration of the leveling control plate 100 or the first channel-bar 300 or the second channel-bar 400, and the like. It may be installed on the lower end of (500).

FIG. 8 is a view illustrating a coupling structure of the leveling control plate 100, the first channel-bar 300, the second channel-bar 400, and the finishing panel 500, and FIG. 9 is a horizontal view of the leveling control panel 100. The first channel-bar 300 is disposed on the plate 120 is a view showing a configuration.

As shown in FIGS. 8 and 9, the first channel-bar 300 is fastened on the horizontal plate 120 of the leveling control plate 100, and both ends of the first side of the first channel-bar 300 are opened. Both ends of the open side of the second channel-bar 400 are coupled to the coupling protrusion 330 formed in the coupling protrusion 330, and the finishing panel 500 is closed at the other side of the second channel-bar 400. The fixing piece 700 is fastened together to the finishing panel 500 and the second channel-bar 400 to be coupled. In this case, the fixing piece 700 may be fastened through the finish panel 500 and the second channel-bar 400 and may also be fastened to the first channel-bar 300.

The first channel-bar 300 fastened on the horizontal plate 120 may be adjusted in a front and rear direction (XX 'direction) along the front and rear leveling holes 121 formed in the horizontal plate 120. .

As shown in FIG. 9, the first channel-bar 300 is preferably formed in a bar shape of approximately 'D' shaped as a channel-bar shape.

That is, the first channel-bar 300 forms a square pipe shape in which one side is opened by forming the support plate 310 and the bent plate 320 which are bent from both ends of the support plate 310, respectively.

In this case, the bending plate 320 is disposed on the horizontal plate 120 to face the finishing panel 500, and the front and rear leveling holes 121 and the bending plate 320 formed in the horizontal plate 120 are disposed. The first channel-bar 300 is fastened on the horizontal plate 120 of the leveling control plate 100 by the fastening bolt 600 penetrating.

The position of the first channel-bar 300 may be adjusted in the front-rear direction (X-X 'direction) along the front-rear leveling hole 121 formed in the horizontal plate 120.

In this case, the bending plate 320 may be formed in a plurality of left and right leveling holes 321 long in the longitudinal direction of the folding plate 320 at regular intervals.

At this time, according to the position of the left and right leveling holes 321 formed in the bending plate 320 through which the fastening bolt 600 is simultaneously passed and the front and rear leveling holes 121 formed in the horizontal plate 120, the horizontal plate ( The position of the first channel-bar 300 fastened on the 120 may be adjusted in the front-rear direction (XX 'direction) as well as in the left-right direction (ZZ' direction).

That is, the position of the leveling control plate 100 may be adjusted in the vertical direction (YY 'direction) by the horizontal plate leveling hole 111, and the first channel-bar 300 may be controlled by the front and rear leveling holes 121. ) Can be adjusted in the front-rear direction (ZZ 'direction), and can be adjusted in the left-right direction (ZZ' direction) by the left and right leveling holes 321, thereby adjusting the position of the first channel-bar 300. The up and down direction, the front and rear direction and the left and right directions can be adjusted at the same time.

At this time, the nut (N) is fastened to both the horizontal plate 120 and the bending plate 310 to the fastening bolt 600, the nut (N) and the horizontal plate 120 and the nut (N) and It is preferable that the washer W is inserted between the bending plates 320.

10 is a view showing the configuration of the coupling protrusion 330 formed on the bending plate 320 of the first channel-bar 300.

The coupling protrusion 330 is formed to protrude along the longitudinal direction of the bending plate 320, it is preferable that a plurality of at regular intervals is formed to maintain a constant interval.

The coupling protrusion 330 is formed with a protrusion 331 extending from both ends of the coupling protrusion 330 to protrude. At this time, the protrusion is preferably processed in a curve that the outer peripheral surface toward the bent plate (320).

The concave portion 332 is formed at the lower end of both ends of the coupling protrusion 330 by the protrusion 331.

At this time, the second channel-bar 400 is open at both ends of the one side is inserted into the concave inlet 332 and engaged with the coupling protrusion 330 is coupled to the first channel-bar 300.

11 is a view showing the configuration of a second channel-bar.

The second channel-bar 400 has a channel-bar shape, and both ends of one side of which are open are engaged with the coupling protrusion 330 and fastened to the first channel-bar 300. At this time, the shape of the channel-bar is as described above.

The second channel-bar 400 forms an opposing plate 410 and a clip plate 420 that is bent from both ends of the opposing plate 410, and each end of the clip plate 420 is the coupling protrusion. 330 is installed to engage with the engagement.

At this time, the clip plate 420 may be further formed with a hook portion 430 that each end of the clip plate 420 is bent inward to form a tooth.

When the engaging portion 430 is formed with the concave indentation 332 in the engaging projection 330, the engaging portion 430 is inserted into the concave indentation 332, and the engaging projection 330 is the clip plate 420. It is possible to combine the first channel-bar 300 and the second channel-bar 400 more firmly by being engaged by the ().

At this time, the locking portion 430 is preferably bent upward, facing the counter plate 410. The hooked portion 430 that is bent upward may perform the same function as the shark teeth to more firmly combine the first channel-bar 300 and the second channel-bar 400.

In this case, the upwardly bent engaging portion 430 is bent upward to have a constant inclination angle (θ), the inclination angle is 10 degrees to 25 degrees upward value based on the imaginary line connecting both ends of the clipboard. It is desirable to have. This is to increase the fastening force by engaging the engaging portion 430 in the form of shark teeth (Jaw, jaw) to the engaging projection 330, as above, bent in the range of 10 degrees to 25 degrees upward value In this case, the engaging portion 430 performs the same function as the jaw in the recess 332 formed in the coupling protrusion 330 to the coupling protrusion 330, so that the first channel-bar 300 and the second channel -The fastening force of the bar 400 is increased to the maximum.

At this time, it is preferable to further form an upwardly bent protrusion 412 toward the opposing plate 410 at the end of the locking portion 430. That is, the protrusion 412 is caught on the upper side of the recess 332 formed in the coupling protrusion 330, so that the clip plate 420 is firmly coupled to the coupling protrusion 330.

The opposing plate 410 of the second channel-bar 400 is formed with an uneven portion 411 is formed along the center line in the longitudinal direction, the coupling hole through the fixing piece 700 is formed in the uneven portion 411 412 may be formed.

12 and 13 are views illustrating a configuration in which the second channel-bar 400 is fastened to the first channel-bar 300, and a configuration in which the finishing panel is coupled to the second channel-bar.

As shown in FIGS. 12 and 13, the second channel-bar 400 is coupled to engage the engaging protrusion 330 of the first channel-bar 300.

That is, the coupling protrusion 330 is interposed between the clip plate 420 is engaged.

The finishing panel 500 is coupled to the opposing plate 410 of the second channel-bar 400.

At this time, the finishing panel 500 is coupled to the opposing plate 410 by a fixing piece 700, the fixing piece 700 is fastened through the closing panel 500 and the opposing plate 410 to be fastened. Is installed.

In this case, the concave-convex portion 411 and the coupling hole 412 may be formed in the opposing plate 410, and the fixing piece 700 may be fastened through the coupling hole 412.

Coupling and fixing of the finishing panel 500 by the fixing piece 700, the fixing piece 700 is fastened through the finishing panel 500 and the opposing plate 410 or the finishing panel 500 As described above, the counter plate 410 and the support plate 310 of the first channel-bar 300 may be penetrated and fastened.

Protruding portion 331 and the concave portion 332 is formed on the engaging projection 330 and the clip plate 420 by the locking portion 430 or the locking portion 430 and the projection 431 is formed, thereby, the clip plate The coupling protrusion 330 is sandwiched between the 420 is firmly engaged.

14 is a view illustrating a coupling relationship in which the clip plate 420 is engaged with and engaged with the coupling protrusion 330.

Referring to FIG. 14, when the coupling protrusion 330 is positioned between the clip plates 420 and the second channel-bar 400 is pushed toward the first channel-bar 300, the clip plate 420 is provided. It can be seen that the engaging portion 430 of the coupling protrusion 330 is carried over the protrusion 331 is inserted into the concave inlet 332 is engaged.

Therefore, since the second channel-bar 400 can be attached to the coupling protrusion 330 in a clip manner, the construction is convenient.

In addition, after the coupling protrusion 330 is bound by the clip method, the second channel-bar 400 may move horizontally in the vertical direction (YY 'direction), thereby positioning the second channel-bar 400. The adjustment is convenient.

When the second channel-bar 400 is separated from the first channel-bar 300, the clip plate 420 may be separated from each other by being separated.

By the above-described configuration of the first channel-bar 300 and the second channel-bar 400, the second channel-bar 400 may be easily attached to and disassembled from the first channel-bar 300.

Paint finish 30 is coupled to the outer surface of the finish panel 500.

At this time, the heat insulating material 20 is composed of an inorganic heat insulating material of non-shrinkable and non-combustible material, including an inorganic heat insulating material including glass wool, mineral wool, and aluminosilicate. It is preferred to be configured.

The glass wool is an inorganic artificial mineral fiber insulation of fiberized after melting at high temperature with silica sand as the main raw material, the mineral wool is an inorganic mineral fiber thermal insulation of fiberized inorganic fiber after melting at high temperature using calcium silicate-based photoresist as a main raw material, In the case of the inorganic heat insulating material including the glass wool and the mineral wool, it is composed of a non-combustible material, thereby ensuring safety of fire and having no toxic gas.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, I will understand. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

10: concrete base material 20: insulation
30: paint finish 100: leveling throttle
110: vertical plate 111: horizontal plate leveling hole
20: horizontal plate 121: front and rear leveling hole
200: anchor bolt 300: first channel-bar
310: support plate 320: bending plate
321: left and right leveling holes 330: engaging projection
331: protrusion 332: recessed portion
400: second channel-bar 410: facing plate
411: uneven portion 412: coupling hole
420: clip 430: locking portion
431 projection 500: finishing panel
600: fastening bolt 700: fixing piece
800: insulation track 810: connecting plate
820: insulation contact plate 830: finish panel contact plate
N: Nut W: Washer
θ: tilt angle
X-X ': forward and backward axis
Y-Y ': Up and down axis
Z-Z ': Left and right axis

Claims (14)

One side is fixed to the concrete base surface and the other side is installed to penetrate the heat insulating material anchor bolt for fixing the heat insulating material to the concrete base surface;
A leveling control plate fastened to the other side of the anchor bolt to form a vertical plate tightly fixed to the heat insulating material, and a horizontal plate connected to a horizontal plate at an upper end of the vertical plate;
A channel-bar shape, the first channel-bar being fastened on the horizontal plate so that one end of the open side faces the finishing panel and forming a plurality of coupling protrusions on both ends of the open side; And
A channel-bar shape, the second channel-bar being fastened so that both ends of the open side is engaged with the coupling protrusion and the closing panel coupled to the other closed side;
Panel finish type external insulation structure comprising a.
The method of claim 1, wherein the panel-finished outer insulation structure,
And a fixing piece that is fastened through the finish panel and the second channel-bar or fastened through the finish panel and the second channel-bar and the first channel-bar.
The method of claim 1,
Longitudinal horizontal plate leveling hole is formed in the vertical plate,
The other end of the anchor bolt is fitted into the horizontal plate leveling hole and fastened, so that the position of the leveling control plate can be adjusted in the vertical direction, panel finish type external insulation structure.
The method of claim 1,
Longitudinal front and rear leveling holes are formed in the horizontal plate,
The first channel-bar forms a square pipe shape in which one side is opened by forming a support plate and a bending plate that is bent from both ends of the support plate, respectively.
The horizontal panel and the bending plate are fastened by the fastening bolt penetrating the front and rear leveling holes and the bending plate, so that the position of the first channel-bar can be adjusted in the front and rear directions on the horizontal plate. Insulation structure.
5. The method of claim 4,
The bending plate is formed with a long left and right leveling hole,
The bent plate is fastened to the horizontal plate by fastening bolts passing through the left and right leveling holes and the front and rear leveling holes, so that the position of the first channel-bar can be adjusted in the left and right directions simultaneously with the front and rear directions on the horizontal plate. Panel finish external insulation structure, characterized in that there is.
The method of claim 1,
The engaging projections are formed by protruding portions extending from both end portions thereof to form recesses inwardly formed on both sides of the engaging projections.
The second channel-bar is a panel-ended outer insulation structure, characterized in that both ends of the open one side is inserted into the fastening recess and coupled to the first channel-bar in engagement with the engaging projection.
The method of claim 1,
The second channel-bar forms an opposing plate facing the finishing panel and a clip plate bent from both ends of the opposing plate;
Panel closure type external insulation structure, characterized in that the clip plate is coupled to engage between the engaging projection.
The method of claim 7, wherein
The opposing plate is formed with an uneven portion along the centerline in the longitudinal direction of the opposing plate, the coupling hole is formed in the center of the uneven portion,
And a fixing piece that is fastened through the closing panel and the coupling hole or fastened through the closing panel and the coupling hole and the first channel-bar.
The method of claim 7, wherein
The clip plate is further formed with a latching portion bent inwardly,
The engaging projections are formed with fastening recesses inwardly formed on both sides of the engaging projections by forming protrusions extending from both end portions thereof.
And the engaging portion is inserted into the fastening recess and coupled to the clip plate to engage the engaging projection.
10. The method of claim 9,
The locking portion of the panel-finished outer insulation structure, characterized in that formed to be upward toward the opposite plate side.
The method of claim 10,
The locking portion is formed upward to have a constant inclination angle (θ) toward the opposite plate side,
The inclination angle (θ) is a panel finished external insulation structure, characterized in that formed to have a value of 10 to 25 degrees upwards with respect to the imaginary line connecting both ends of the clip plate.
The method of claim 11,
The locking portion of the panel-finished outer insulation structure, characterized in that the projection is formed extending from the end to the upper side.
The method of claim 1,
In the lower part of the insulation and the finishing panel,
One side forms a heat insulating material contact plate that is in close contact with the heat insulating material and the other side forms a finish panel contact plate in close contact with the finish panel, and the heat insulation track consisting of a connecting plate connecting the heat insulating material contact plate and the finish panel contact plate. Panel finish type outer insulation structure, characterized in that it further comprises.
The method of claim 1,
The insulation is a non-shrinkable, non-flammable inorganic insulation, panel finish type, characterized in that consisting of glass wool (Wool), mineral wool (Mineral-Wool) and alumina silicate (Alumina-Silicate) External insulation structure.

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