KR101657683B1 - Thermal insulation material with waterproofing properties and the method of constructing the same - Google Patents

Abstract

The present invention discloses a high-strength thermal insulation structure for heat-bridging and waterproofing and a construction method thereof.
The high strength heat insulating structure for thermal bridge interception and waterproofing according to the present invention and the method of constructing the same include a panel having a seating part having a positive step at one end and a supporting part having a negative step at at least one end In this case, the impact resistance and structural performance of the insulation structure are strengthened by the formation of the high strength fiber layer and the impact protection mortar layer in the outer insulation work of the building or the waterproofing and the rescue work of the building, It is possible to maximize the insulation performance of the building by blocking the thermal bridge and enhancing the airtightness of the building. Minimizing the inhibition factor of smoothness due to the step of the insulation joint at the time of construction and reducing the construction time And the ease of construction, and the shrinkage and expansion of the heat insulating material, It is possible to effectively prevent moisture from being blown out by a separate channel while preventing cracks due to water leakage and the swelling of the coating film by blocking the moisture such as snow and rain after the installation due to perfect airtight construction of the joint of the heat insulating material, It maximizes durability and secures watertightness. It is easy to construct and maintain complex parts with simple assembly construction method. It maximizes heat insulation performance and airtightness performance to reduce unnecessary heat loss, improve building energy efficiency, It has excellent impact resistance, structural performance, insulation performance, workability, smoothness, energy efficiency, durability degradation and anticorrosive (inner) performance which are problems of existing external insulation work or waterproofing and anticorrosion It is possible to maximize the external insulation performance and the waterproof / anticorruption performance of the building.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a high-

More particularly, the present invention relates to a high strength thermal insulation structure for waterproofing and waterproofing, and more particularly, to a heat insulation structure and a construction method thereof, And it is possible to maximize the insulation performance of the building by blocking the thermal bridge and enhancing the airtight performance by the method of being assembled and installed tightly between the insulating structures and minimizing the inhibition factors of smoothness due to the step of the insulating joint at the time of construction, It is easy to shorten construction time and workability because it does not require separate mortar plugging work at work, and effectively prevents cracks occurring at joints between insulation materials due to shrinkage and expansion of insulation materials, and provides perfect airtight construction of insulation joints, Cracks due to water leakage by blocking moisture such as rain, And it is easy to remove moisture with a separate channel. It maximizes the durability improvement and water tightness of the building, and it is easy to construct and maintain complex parts by simple assembly construction method, and to maximize insulation performance and airtight performance It improves the energy efficiency of buildings by reducing unnecessary heat loss, and demonstrates excellent stability of road safety for securing urban green areas and rooftop greening. It can provide excellent impact resistance, structural performance, insulation performance (EN) A heat - insulating and waterproofing high - strength thermal insulation structure for a building, which can maximize the external insulation performance and the waterproofing / anticorrosion performance of a building by completely improving the workability, smoothness, energy efficiency, durability,

The existing external adiabatic method generally consists of a process of adhering the insulation material, forming a mortar layer, reinforcing the mortar layer, and finishing. In the process of adhering the adiabatic material, EPS (Styrofoam) Which is attached to the outside of the building in a floating manner. The mortar layer forming process is a process of finishing the cementitious base material on the surface of the thermal insulation material. The mortar layer reinforcement process is a process of impregnating glass fiber to prevent the thermal insulation material from breakage. Generally, It is composed of two reinforcement stages of total assembly. When the mortar layer is sufficiently cured, the final finishing process is carried out using finishing paints such as paint, stone finishing materials, and external thermal finishing materials (standard finishing materials). In this case, a primer coating process for improving the adhesion performance depending on the type of the finishing material, a middle coating process for forming various patterns and textures, a top coating material coating process for preventing contamination of the finish surface, EPS (Styrofoam), which is cheap in price, is mainly used as an insulation material used in adiabatic process. In case of EPS, the strength is comparatively weak and it is damaged by external impact such as typhoon, wind pressure, And the insulation performance is deteriorated due to the failure of airtightness due to the breakage and dropping of the insulation material, resulting in a serious problem in the structural performance, durability, stability and energy efficiency of the building.

In addition, since the thermal insulation material is adhered in a floating manner using a cementitious base material at the time of construction, the smoothness is lowered due to the step between the heat insulating materials, and accordingly, a separate surface smoothing operation for improving the smoothness is required before proceeding with the subsequent process. The construction period was unnecessarily long, and the construction was not easy.

In addition, because EPS is a polymer organic compound, shrinkage and expansion due to changes in temperature and humidity are inevitable. In the case of the conventional external insulation method, the contrast is insufficient, , The durability of the whole building is deteriorated due to the leakage of the gap in the joint, and the appearance of the building is degraded.

On the other hand, it is necessary to make waterproofing works to prevent leaks on roofs and roofs of buildings. In general, asphalt waterproofing method, sheet waterproofing method and film waterproofing method are mainly used. Recently, Many complex waterproofing methods suitable for the situation are applied. In the case of these waterproofing methods, since it is mainly applied to a roof or a roof facing directly to the external environment, it is inevitably affected by direct sunlight. However, since most of the waterproofing works without the insulation process, external heat such as direct sunlight is absorbed directly into the building, which causes the heating and cooling load to increase, which is a major cause of deteriorating the energy efficiency of the building.

Also, cracks may occur in the construction site due to the temperature difference, surface swelling may occur due to moisture absorption, complicated areas can not be easily constructed, partial repair is difficult, and watertightness at the sheet-to- There are many problems. Especially, in order to strengthen the eco-area ratio applied to the redevelopment of various new cities and new towns being promoted by the government and the local governments, and to secure the durability of the rooftop greening market, There has been a demand for a high-durability inner (root) layer capable of responding to acupuncture input.

As a result, there are various problems in the conventional exterior insulation and waterproofing construction, and thus it is possible to improve the impact resistance, the structural performance, the insulation performance, the workability, and the energy efficiency in the construction of the external insulation or waterproofing of the building In addition, there is a need to develop functionalized insulation structures and construction methods that can reduce the environmental pollution, the lack of green space and the heat island phenomenon in urban areas.

Accordingly, the first technical problem to be solved by the present invention is to strengthen the impact resistance and structural performance of the heat insulating structure by forming the high strength fiber layer and the impact protection mortar layer in the outer insulation work of the building, waterproofing and anticorrosive work of the building, It is possible to maximize the insulation performance of the building by blocking the thermal bridges and enhancing the airtightness of the building. In addition, it is possible to minimize the inhibition of smoothness caused by the step of the insulation joint at the time of construction, It is easy to shorten the construction period and easy to construct, effectively prevents the cracks occurring at the joint between the insulation due to shrinkage and expansion of the insulation, and blocks the moisture such as snow and rain after the construction by perfect sealing of the joint of the insulation. It is possible to prevent the occurrence of cracks and swelling of the coating film, It is easy to remove, maximizes building durability and watertightness, simplifies construction and maintenance of complex parts with simple assembly construction method, maximizes insulation performance and airtightness, reduces unnecessary heat loss, And it shows excellent stability of road stability for green area of city center and rooftop greening. As a result, impact resistance, structural performance, insulation performance, workability, smoothness, energy efficiency, durability deterioration , Which is capable of maximizing the external heat insulation performance and the waterproofing / anticorrosion performance of the building by completely improving the performance of the interior and the exterior (interior) of the building.

The second technical problem to be solved by the present invention is to strengthen the impact resistance and structural performance of the heat insulating structure by forming the high strength fiber layer and the shock protection mortar layer in the outer insulation work of the building or the waterproofing and the crossing work of the building, It is possible to maximize the insulation performance of the building by blocking the thermal bridges and enhancing the airtightness of the building. In addition, it is possible to minimize the inhibition of smoothness caused by the step of the insulation joint at the time of construction, It is easy to shorten the construction period and easy to construct, effectively prevents the cracks occurring at the joint between the insulation due to shrinkage and expansion of the insulation, and blocks the moisture such as snow and rain after the construction by perfect sealing of the joint of the insulation. It is possible to prevent the occurrence of cracks and swelling of the coating film, It is easy to install, maximizes building durability and watertightness, facilitates construction and maintenance of complex parts with simple assembly construction method, maximizes insulation performance and airtightness, and improves energy efficiency of buildings by reducing unnecessary heat loss. And it shows excellent stability of road performance for securing urban green areas and rooftop greening. As a result, it is possible to improve the impact resistance, structural performance, insulation performance, workability, smoothness, energy efficiency, durability, And to provide a method of constructing a high-strength heat insulating structure for heat-bridging and waterproofing, which can maximize the external heat insulation performance and the waterproofing / anticorrosion performance of the building by completely improving the performance of the interior (inside)

In order to solve the first technical problem described above, the present invention is characterized in that it comprises a panel having a seating part having a positive step on at least one end and a supporting part having a negative step on at least one end Provided is a high-strength heat insulating structure for heat-bridging and waterproofing.

According to an embodiment of the present invention, a groove groove may be formed on one surface of the seating portion or the receiving portion.

According to another embodiment of the present invention, in addition to the seating part, a groove groove may be formed on one side of an empty seating part forming one end of the panel or on one side of a blank receiving part forming one end of the panel in addition to the receiving part.

According to another embodiment of the present invention, the thickness at which the receiving portion and the seating portion overlap may be less than or equal to the thickness of the panel.

According to another embodiment of the present invention, the seating portion or the receiving portion may be provided at two adjacent ends of the wall panel.

According to another embodiment of the present invention, the seating portion or the receiving portion of the panel may be formed over the entire one end portion.

According to another embodiment of the present invention, the receiving portion may be provided with a perforation hole.

According to another embodiment of the present invention, a plurality of the panel may be arranged so that the receiving portion and the receiving portion overlap each other.

According to another embodiment of the present invention, the thickness of the receiving portion and the seating portion overlapping each other may be less than or equal to the thickness of the panel.

According to another embodiment of the present invention, the panel may be provided with a glass fiber mesh material formed in the form of a nonwoven fabric or a mesh.

According to another embodiment of the present invention, a cement-based board, a magnesium-based board, a ceramic-based board, or a new material board may be further included on one side of the panel.

According to another embodiment of the present invention, the panel may further include a stones finish, an external heat-insulating finish, a paint, a multi-pattern paint, a ceramic paint or a metal panel.

The present invention, in order to solve the second technical problem described above, includes a step S1 of fixing the panel to a wall surface, and a step S2 of securing and fixing the receiving portion of the panel and the seating portion of the other panel in an overlapping manner. And a method of constructing an outer insulation of a building using the waterproof high strength thermal insulation structure.

According to an embodiment of the present invention, the fixing in step S1 or step S2 may be performed by curing through adhesive mortar or urethane foam.

According to another embodiment of the present invention, a step of adding a crack preventing material such as a polyurethane film, a PET film, an FRP film, or an acrylic resin may be added between the receiving portion and the receiving portion.

According to another embodiment of the present invention, the crack preventing material may further include a crack preventing auxiliary material such as urethane foam or an adhesive for strengthening adhesion and preventing cracking.

According to another embodiment of the present invention, the fixing in the step S1 or S2 may be the insertion of the fixing member into the perforation hole.

According to another embodiment of the present invention, the fixing may be performed by inserting a T bar having a T-shaped cross section into the groove groove of the panel.

According to another embodiment of the present invention, the step S2 may further include the step of attaching an outer wall finishing material such as a stone finishing material, an outer heat insulating finishing material, a paint, a multi-pattern paint, a ceramic paint, a metal panel or a coating material.

According to another embodiment of the present invention, a step of attaching a urethane-based waterproofing material, an epoxy-based waterproofing material, a rubber-based waterproofing material, a sheet waterproofing material, a film-type waterproofing material, a PET film or FRP- .

According to the present invention, it is possible to effectively protect a building from external impacts in a waterproofing work or a wall construction of a building, and to prevent water leakage such as leakage of water by blocking moisture such as snow and rain, And the mutual airtightness, workability, and watertightness of the heat insulating material are ensured, which can maximize the external heat insulating performance and the waterproof performance.

1 is a front view of a panel according to the present invention,
Figure 2 is a side view of the panel according to the invention,
FIG. 3 is a view showing another embodiment of the panel side according to the present invention,
Fig. 4 is a perspective view showing the overlapping shape of the panel according to the present invention,
5 is a view showing a cross section of a folded shape of a panel according to the present invention,
6 is a flowchart of a construction method according to the present invention,
7 is an exploded perspective view of a T bar and a panel according to an embodiment of the present invention,
FIG. 8 is a cross-sectional view of a configuration in which a panel is installed by a T-bar according to an embodiment of the present invention. FIG.

Hereinafter, the present invention will be described in more detail.

While the present invention has been described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention. . Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

Fig. 1 is a front view of a panel according to the present invention, Fig. 2 is a side view of a panel according to the present invention, Fig. 3 is a view showing another embodiment of a panel side according to the present invention, FIG. 5 is a view showing a cross section of a folded shape of a panel according to the present invention, FIG. 6 is a flowchart of a construction method according to the present invention, and FIG. 7 is a cross- FIG. 8 is a cross-sectional view of a configuration in which a panel is installed by a T bar according to an embodiment of the present invention. FIG.

As shown in FIGS. 1 to 8, a panel 100 of a high-strength heat insulating structure for thermal-bridge interception and waterproofing according to the present invention includes a seating part 110 having a positive step at one end and at least one end part And a receiving portion 120 having a negative stepped portion.

The positive and negative steps of the positive and negative steps are defined as a seating part 110 and a supporting part 120, respectively, This is because the space for forming one end of the panel in addition to the seating part 110 is an empty seating part 110 'and a space for forming the other end of the panel is added to the receiving part 120, (120 ').

In addition to the seating part 110, one side of the empty seating part 110 'forming one end of the panel or one side of the blank receiving part 120' forming one end of the panel in addition to the receiving part 120 A groove groove 130 may be provided on one side of the panel 100 so that one side of the empty seating portion 110 'or the empty side receiving portion 120' is in contact with the panel.

It is possible to prevent cracks between the panels when the expansion and contraction due to the temperature difference through the groove grooves 130 is interrupted, as well as provide an excellent discharge passage, which is helpful for improving the durability.

The thickness t1 + t2 of the receiving portion 120 and the receiving portion 110 may be less than the thickness T of the panel. The thickness t1 of the receiving portion 120 and the thickness (T2) of the panel (110) is thinner than the panel thickness (T), thereby securing a space therebetween to prevent the panel from cracking during expansion and contraction due to temperature difference, It is possible to secure a filling space for the ash.

In addition, the seating part 110 or the receiving part 120 may be formed at the two ends of the one end or adjacent to each other, so that a plurality of the panels 100 can be arranged horizontally, .

The receiving part 120 is provided with a perforation hole 140 so that a fixing member such as an anchor bolt which can be easily inserted and fixed into the wall W can enter and be fixed in the perforation hole 140.

In addition, the panel 100 may be mounted vertically on the wall W so as to be arranged so that the receiving unit and the receiving unit overlap each other. In this case, the receiving unit 120 and the mounting unit 110 are overlapped The thickness t1 + t2 is less than or equal to the thickness T of the panel, and a detailed description thereof will be omitted herein.

In addition, the fixing member may be a T bar 130 'having a T-shaped cross section, which has a T-shaped cross section and supports a plurality of the panels 100 as a long bar.

The T bar 130 'may be inserted into the groove groove 130 of the panel to support the panel. The T bar 130' may be previously fixed to the wall W by means of an anchor bolt.

Accordingly, it can be seen that the groove groove 130 is configured as a medium for fixing.

The panel 100 may be provided with a glass fiber mesh material 150 formed in the form of a nonwoven fabric or mesh, thereby preventing cracking during shrinking and expansion due to a temperature difference, preventing splashing when damaged by an external force, It helps to improve.

The panel 100 may further include a cementitious board, a magnesium-based board, a ceramic-based board or a new material board, or a stone finishing material, an external finishing material, a paint, a multi-pattern paint, a ceramic- In addition, strength, heat insulation and aesthetics can be realized.

And a step S2 of fixing the panel to the wall surface and fixing the seating part of the panel to the seating part of the other panel so as to be overlapped with each other and fixing the building to the building using the high strength heat insulating structure for thermal bridging, A panel 100 having a mounting part 110 having a positive step at one end and a receiving part 120 having a negative step at at least one end, (S).

The wall (W) is gathered by a tie pin, a half-life, a granule so that there is no protruding part of a wing splattering in four directions when the concrete is poured, and dust, sludge, It is strongly rubbed off with a broom, then blown out with a blower to completely remove it.

The fixing may be performed by curing through an adhesive mortar or a urethane foam or by inserting a fixing member such as an anchor bolt into the perforation hole 140. When the fixing member is fixed The resistance to shrinkage expansion due to the temperature difference may be more excellent.

In step S2, the support part 120 of the panel and the seating part 130 of the other panel are arranged and fixed in an overlapping manner. The support part 120 and the seating part 130 are formed of poly A urethane film, a PET film, a FRP film, or a crack preventing material which is an acrylic resin can be further added to increase the heat insulating property.

Further, the crack preventing material may further include a crack preventing auxiliary material such as urethane foam or an adhesive for reinforcing adhesion and preventing cracks, thereby enhancing adhesive strength and preventing cracking, as well as expanding the heat insulating property according to the design of the building.

In addition, depending on the characteristics of the building, the outer wall finishing material can further adhere the waterproofing material to the outside of the panel 100. The outer wall finishing material may include a stone finishing material, an outer heat insulating finishing material, paint, various pattern paint, ceramic paint, As the waterproof material, a urethane-based waterproofing material, an epoxy-based waterproofing material, a rubber-based waterproofing material, a sheet waterproofing material, a film-type waterproofing material, a PET film or a FRP-based film reinforced by the movement performance can be used.

As described above, the panels 100 are arranged vertically, horizontally, and horizontally in a plurality of arrangements, and the seating portions 110 or the receiving portions 120 of the plurality of panels 100 are disposed horizontally or vertically, And fixed by means of adhesive mortar or urethane foam.

Claims (20)

delete delete delete delete delete delete delete delete delete delete delete delete And a panel having a seating part having a positive step at least at one end and a receiving part having a negative step at at least one end,
A groove groove is formed on one surface of the seating portion or the receiving portion,
A groove groove is formed on one side of an empty seating portion forming one end of the panel in addition to the seating portion or on one side of a blank receiving portion forming one end of the panel in addition to the receiving portion,
A step S1 of securing a panel having a thickness equal to or less than the thickness of the panel to the wall surface, the thickness of the panel being overlapped with the receiving portion and the seating portion, wherein the receiving portion and the seating portion are overlapped; And
(S2) of arranging and fixing the receiving portion of the panel and the seating portion of the other panel in an overlapping manner,
Wherein the step S1 or S2 is performed by inserting a T bar having a T-shaped cross section in the groove groove of the panel.
14. The method of claim 13,
Wherein the fixing step S1 or step S2 is performed by curing through an adhesive mortar or a urethane foam.
delete delete 14. The method of claim 13,
Wherein the securing step S1 or S2 is performed by inserting a fixing member into the perforation hole.
delete delete delete

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