KR20140116367A - Solution with enclosed internal air cavity for Exterior Insulation Finishing System - Google Patents

Abstract

The present invention relates to a heat insulation material for an exterior insulation finishing system (EIFS) method. The present invention constructs multiple thin heat insulation materials formed by molding to form an overlapping multi-layer structure instead of using one thick heat insulation material like in a conventional method to form an individually sectioned and small air layer on the rear surface of each heat insulation material while preparing a rim on the mold to enable the air layer to be sealed, thereby enabling high thermal insulation performance. The present invention applies the principles of several thin layers of clothes having higher thermal insulation performance through the air layers in-between compared to a single thick clothing on the outer wall of a building.

Description

TECHNICAL FIELD [0001] The present invention relates to an external insulation finishing system having a closed intermediate air layer,

Exterior Insulation Finishing System (EIFS), which satisfies the external heat by using the insulation outside of the outer wall of the building, and finishes the building with the mortar plaster on the outer surface of the insulation. .

Globally, all countries are struggling to save energy at the national level in order to reduce carbon emissions. Energy conservation is one of the most common tasks across all industries, but one of the ways to reduce the energy consumed by buildings is the easiest to obtain energy savings.

The external insulation finishing method, in which the insulation is attached to the exterior wall of the building and the exterior of the insulation is covered with mortar by finishing the exterior of the building, has the lowest cost of installation and the highest insulation effect It is widely used around the world because of its advantages.

In an external heat insulation plaster finishing method, a heat insulating material is attached to an outer wall surface of a building.

The insulation performance of the wall depends on the inherent thermal conductivity value of the insulation to be used and the thickness of the insulation used.

From here,

According to the academics, the thermal resistance varies with the thickness of the insulation. The insulation effect is not directly proportional to the thickness of the insulation.

1 is a graph showing a change in thermal resistance value according to a change in thickness of a heat insulator.

According to the graph of FIG. 1, the thickness of the heat insulating material is almost proportional to the thickness, and the heat conduction rate is rapidly lowered. On the other hand, as the thickness of the heat insulating material exceeds the certain thickness, the heat conduction ratio does not decrease significantly.

That is, as the thickness of the heat insulating material exceeds the certain thickness, the increase in the heat insulating effect is small, resulting in a reduction in the efficiency relative to the input cost.

Energy conservation design standards for current buildings in Korea have been greatly strengthened. From 2015, new buildings will be reinforced with insulation standards close to passive houses.

In case of wall insulation in domestic seasonal environment, the thickness of insulation material should be 300 ~ 400mm as the case of Fig.

In contrast to the graph of FIG. 1, the thickness of the insulation over 300 mm is on an inefficient line which is not economically feasible.

The efficiency is much lower than the cost of investing for insulation.

12 is a photograph showing an outer wall constituted by a thick heat insulating material for a passive house.

Energy saving design standards for current buildings - [Enforcement 2014.9.1.] [Ministry of Land Transport and Public Notice 2014-520, 2014.9.1., Some revisions] Homepage of Korea Passive Architects Association The passive rate calculation program of Korea Passive Architecture Association

In the present invention, it is a problem to solve the inefficiency due to the increase in the thickness of the heat insulating material described in Fig.

By using multiple layers of thinner insulation, we intend to achieve a higher insulation effect while greatly reducing the amount of insulation used.

According to the existing laws of Korea, the legal heat-conduction rate of the outer wall of the new building according to the energy conservation design standards of buildings has recently been strengthened to 0.27 W / ㎡ · K or less in the central region, and the environment-friendly building certification standard has reduced the legal heat- And 0.18 W / ㎡ · K for the condition, and the external wall heat conduction rate for the authentication of the passive house, also called zero house, is 0.15 W / ㎡ · K or less.

FIG. 2, FIG. 3, and FIG. 4 are tables for calculating the thickness of the heat insulating material required for each heat insulation criterion using a heat conduction ratio calculation program.

In order to calculate this, the wall structure applied to the calculation of the heat transfer rate is the most commonly applied method of famous brand apartment which is beginning to build in the external insulation system in Korea recently, and the sectional view is shown in the lower left part of the figure.

In addition, the type of insulation applied to the heat rate calculation program was based on the bead method No. 1, No. 3, which is the most widely used in the industry due to its high insulation efficiency against price.

Fig. 2 is a calculation table in the case where the thickness of the heat insulator is 130 mm in order to achieve the legal heat conduction rate of 0.27 W / m < 2 > The calculated value is 0.27 W / m < 2 >

Fig. 3 is a calculation table in the case where the thickness of the insulating material is 200 mm in order to achieve a heat-conduction rate of 0.18 W / m < 2 > The calculated value is 0.18 W / m < 2 >

Fig. 4 is a calculation table when the thickness of the insulation material is 300 mm in order to achieve a passive house certification standard heat conduction rate of 0.15 W / m < 2 > The calculated value is 0.13 W / m < 2 >

As shown in these tables, as the thickness of the heat insulating material increases, the heat conduction rate does not decrease in direct proportion, but has a quadratic function curve shape as shown in FIG. 1. As the thickness becomes thicker, the temperature becomes gradually closer to the horizontal direction and the synergistic effect of the heat insulating performance becomes insignificant.

In the present invention, as means for solving such a problem

The present invention aims at solving the problem by using a thin insulation material in multiple layers without using a single thick insulation material, having an air layer partitioned by a small area between the insulation materials and sealing the air layer well.

Air has a lower thermal conductivity than acceptable insulation.

The published thermal conductivity of air is 0.025 W / m · K at 0 ℃, which is much lower than the thermal conductivity of 0.04 W / m · K, the most widely used bead type No. 3 thermal insulation material in the industry.

If the air layer between the insulation is well formed to perform as an effective insulation layer required in the academic aspect, it will serve as a very good insulation layer.

It's also the air that does not cost money at all.

According to academic theories, convection loss occurs when air flows for any reason in the air layer, and it has little effect as an insulating layer.

For that reason, according to Annex 5 of the current building energy-saving design standard attached to Figure 5 [table of thermal resistance of the hollow layer applied in the calculation of the thermal conductivity], there are two clearly distinguished hollow layers present in the wall.

The table in Fig. 5 is divided into a hollow layer of a factory-produced airtight product and a hollow layer formed on site.

It is necessary to divide the quality of the adiabatic air layer by the difference of the convection loss depending on how well the air layer is sealed and the performance difference.

Since the air layer in the fair grass, which is a representative product of the factory-produced air layer, is a single product, the area of the air layer is small and the airtightness is excellent, but the air layer in the ceiling or in the wall generated in the process It is true that the difference in performance is due to the fact that there is a very large difference in the amount of external air inflow due to a gap between a large number of constituent materials, or a through hole due to an interfacial fire partition or various facilities.

It is easy to understand that it is easy to understand that the insulation effect is influenced by the sealing performance of the generated air layer.

Convection also occurs proportionally as the area of the air layer increases and as the volume increases.

When the direction of the air layer is the vertical direction, convection occurs in a larger amount than in the air layer in the horizontal direction.

Only the stationary air layer without convection acts as an effective heat transfer resistor.

It is the insulation effect of the closed air layer which gives unexpected adiabatic effect to attach the so-called 뽁뽁 포장 which is used as the packing material of the cracked object for the additional insulation of the window window of winter in the common life in our life.

Therefore, the present invention proposes a method for obtaining an effect as an effective heat insulating layer by preventing a convection loss from occurring due to the fact that a hollow layer, which is an air layer, is easily installed between the heat insulating materials, do.

In the present invention, all of the heat insulating materials for external heat insulation are installed on the site, but each air layer generated by the heat insulating material is partitioned into a very small unit area, and the airtightness is very easily ensured so that the structure can serve as an effective heat insulating air layer. .

The object of the present invention is to obtain a better heat insulation performance while using less heat insulation materials used in buildings.

FIG. 6 is a view showing a case in which a closed air layer is oriented according to an embodiment of the present invention, and a 50 mm thick insulation material is laminated on the same wall structure with the same material and thermal conductivity to form an effective air insulation layer having a thickness of 25 mm. In other words, the thickness of only the total heat insulation material was 100 mm, and the heat transfer coefficient was 0.12 W / ㎡ · K.

4 is 0.12 W / m < 2 > K, which is lower than 0.13 W / m < 2 > K, which is the heat conduction rate obtained by using a heat insulating material of 300 mm thickness for passive house reference.

According to the calculation value, the total thickness of the heat insulating material of 100 mm is used in the present invention,

It is a result that the heat conduction rate lower than the thickness of the heat insulating material of 300mm in the conventional method can be obtained.

Of course, unlike the sealing performance of the factory-produced fair glass, 50mm thick bead insulation (called STICHROMOOM) is used. In order to form a closed air layer with low permeability and presence of the material itself, a 2cm wide protruding rim , But it can be predicted that the adiabatic effect is improved to a great extent although the result is not considered.

The present invention can drastically reduce the amount of organic insulating material used for insulation and greatly reduce the carbon emission from the construction process to the entire lifetime of the building.

FIG. 1 is a graph showing the change in the heat conduction rate according to the thickness of the heat insulating material (in the case of the heat insulating material having an applied thermal conductivity of 0.034 W / mK)
FIG. 2 is a table showing the calculation results of the heat conduction rate value when a 130 mm thick insulation material is used in the conventional method
Fig. 3 is a table showing the heat conduction ratio value when the heat insulating material having a thickness of 200 mm is used in the conventional method
Fig. 4 is a table showing the calculation result of the heat conduction rate value when a thermal insulation material having a thickness of 300 mm is used in the conventional method
Fig. 5 is a table 5 of the current building energy saving standard [Heat resistance of the hollow layer applied in calculating the heat transfer rate]
Fig. 6 is a graph showing the results of calculation of the heat conduction rate value when a total thickness of 100 mm is used in the method of the present invention
Fig. 7 is a front view of a mold-shaped heat insulating material according to the present invention
Fig. 8 is a rear view of the mold-shaped heat insulating material according to the present invention
FIG. 9 is a perspective view showing the entirety of a mold for repeatedly arranging the mold-
FIG. 10 is a perspective view illustrating a fixing method of insulators repeatedly arranged in a staggered manner according to the present invention.
Fig. 11 is a photograph showing a case in which a sealing adhesive material 6 of a material suitable for the present invention is applied
Figure 12 is a photograph of a thick insulation for a passive house
13 is a cross-sectional view illustrating the formation of the closed intermediate air layer 5 according to the present invention

Specific details for implementing the present invention are as follows.

9 is an overall perspective view of a process in which a heat-insulating material molded in an appropriate size is installed in a front-back double layer.

As shown in FIG. 9, the respective heat insulating materials are stacked with the joints that are necessarily sealed up to the adjacent heat insulating materials in front of and behind the adjacent heat insulating materials, so that the joints of all the heat insulating materials are installed in such a manner that no joint is formed.

To this end, all of the adjacent heat insulating materials have a structure in which the fastener holes 3 are located at positions where the joints of the heat insulating materials are repeatedly overlapped.

At this time, the sealing adhesive 6 as shown in FIG. 11 should be applied not only to the protruding rim 4 of the heat insulating material, but also to the joint which is in contact with the heat insulating material, so that convection through the gap should not occur.

The required properties of the sealing adhesive 6 are preferably water resistance, airtightness and elasticity and sufficient fluidity during the pot life to install the heat insulating materials.

This is because the inorganic cement mortar usually used in the prior art thermal insulation finishing method is fragile and brittle and tends to break or fall due to various linear expansion displacements of various materials caused by solar heat.

7 shows a front view of a heat insulating material formed in a suitable number of holes 3 for fasteners into which the fastener bolts 2 are inserted, corresponding to wind loads, on the front surface of the heat insulating material molded by a mold.

8 is a rear view of the heat insulating material having a protruding rim 4 of a suitable height for forming an intermediate air layer 5 sealed between the inner heat insulating material 1-1 and the outer heat insulating material 1-2 to be. This protruding rim 4 may further have a protruding rim 4 blocking the compartment, if necessary, so as to define an appropriate area of the closed intermediate air layer 5. If the number of fastener bolts (2) to be fastened to the middle of the heat insulating material increases according to the applied wind load when the building has a higher layer, the protruding rim for dividing the intermediate compartment can be further increased.

The appropriate volume of the sealed intermediate air layer 5 is determined depending on the number and position of the partition walls 4.

The inner layer heat insulating material 1-1 and the outer layer insulating material 1-2 are tightened by one fastener bolt 2 per hole 3 for each fastener to partition the closed intermediate air layers 5 with a small area And is mechanically sealed.

The fastener bolts (2) used are more preferably in the form of screws rather than in the form of a hammer.

10 shows a method of fixing the respective heat insulating materials by using the fastener bolts 2 in a staggered manner.

Even if all the insulation materials are staggered, the fastener holes 3 are formed so as to be coincident with each other. Therefore, it is possible to easily realize a more detailed sealing structure have.

FIG. 13 is a cross-sectional view of the present invention in which a closed intermediate air layer 5 is formed.

The present invention

It is a technique to obtain a larger insulation effect by using less than half of insulation material than conventional method.

Once installed, the effect remains unchanged from the time the building is completed until it is demolished.

 If this technology is activated by the present invention and the insulation material is actually used in half, the effect of reducing the amount of carbon dioxide that is saved over a long period of time, as well as the cost saving effect of the insulation itself, is very large.

Further, the present invention is a technique that can be commonly applied to all industrial fields requiring insulation.

1-1: Inner layer insulation
1-2: Outer layer insulation
2: fastener bolt
3: hole for fastener
4: protruding border
5: Closed intermediate air layer
6: Sealing adhesive
7: Building wall frame
8: Insulation lid

Claims (1)

Among the outer heat-insulating plaster finishing method using a mold-formed heat insulator having a fastener hole (3) for inserting a fastener bolt (2) for fixing a heat insulator on the front surface of the heat insulator,
The molded insulating material is installed so as to be overlapped with the wall surface so as to have a structure protruding at a constant height along the rim on the rear surface of the heat insulating material so as to form a sealed air layer between the respective insulating materials with a predetermined size and shape Thereby forming a plurality of closed intermediate air layers 5 in the middle of the insulation layer.

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