KR101397827B1 - Roof outside insulation waterproofing structure and construction method of the same - Google Patents

Abstract

The present invention provides a roof outside insulation waterproof structure, which can save energy, prevent damage to a waterproof layer by preventing condensation, increase the durability of the waterproof layer, react excellently to the contraction and expansion of a concrete base, and exhibit excellent insulation performance by blocking radiant heat, and a method for constructing the same. The roof external insulation waterproof structure according to an appropriate embodiment of the present invention comprises an insulation layer bonded to the concrete base of the roof of a building and made of one among polyester foam, polyurethane foam, and polystyrene foam; a film insulating layer formed by attaching an aluminum film to the upper surface of the insulation layer; a rubber waterproof layer formed by attaching a self-adhesive modified asphalt sheet to the surface of the film insulating layer; a reinforcing layer formed by attaching non-woven fabric to the surface of the rubber waterproof layer; and a urethane waterproof layer formed by applying urethane to the surface of the reinforcing layer.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a roof waterproof insulation structure,

[0001] The present invention relates to a roof-top external waterproofing structure and a method of constructing the same, and more particularly to a roofing waterproofing structure for a roof, And a method of constructing the same. 2. Description of the Related Art

Generally, the insulation waterproofing treatment of a building refers to a waterproofing function that is cool in summer and warm in winter, and has a waterproof function to prevent leaking of rainwater to a building.

The waterproofing of a building, in its broadest sense, includes waterproofing of the roof and the entire exterior wall of the building, but it is generally preferred that the roof, the parapet and the ceiling, Refers to the treatment of fragile parts.

In the government policy business area, the government occupies more construction part in terms of energy saving and expects to save energy by applying the construction part which expects energy effect to design. However, there is still a great need for leakage and insulation problems that are expected to be most effective in all construction materials.

Particularly, roofs, roofs, etc. are required to be treated with special waterproofing because they can intensively penetrate rainwater. In existing concrete structures, although roofs and the like are under the worst environmental conditions exposed directly to the external environment, waterproof materials actually applied to the roofs are difficult to secure the insulation performance.

In winter and in the summer, the higher the water content according to the concrete temperature and the water content according to the water content of the base surface, the higher the occurrence frequency of defects due to the adhesion problem of the waterproofing material. That is, it is difficult to prevent the tearing phenomenon of the waterproof layer due to bubble phenomenon or breakage due to the steam pressure that is vaporized after the construction. Unless this problem is solved, it is very difficult to prevent swelling and breakage due to the moisture and condensation of the waterproof layer.

Conventional waterproofing construction is highly dependent on constructors. However, in the case of waterproofing the existing surface that does not reinforce the insulating material, the occurrence frequency of defects due to moisture is very high, and the water content of the waterproofing works other than the method in which the mixing ratio between the materials is not precisely maintained or the water is sufficiently removed.

If the insulation performance is improved, the internal and external temperature fluctuations will not only prevent moisture, condensation, especially water problems and waterproof layer swelling, but also provide excellent durability and weather resistance.

U-urethane, which has excellent waterproof property, has been widely used as a waterproof coating structure in underground parking lots or underground structures that do not reinforce insulation, but it has been used as a non-exposed coating waterproofing structure. In view of not considering insulation reinforcement at all, In winter, it is very hot, and in winter it is not only very cold, but also it can not compensate for the problems caused by moisture and dew condensation.

Also. The conventional waterproof structure can be expected to have a waterproof effect to some extent by melting and melting by heat of a torsion lamp or the like which is overlapped between each sheet of asphalt sheets without a heat insulating layer.

However, since the joint portions between the sheets are melted and fused by the heat of the torii lamp, the frequency of occurrence of leakage due to damage between the joints due to overheating is very high, and the effect of waterproofing is low. Especially, underground structures have very high humidity due to external and internal temperature fluctuations, and when they are low, they do not play a long role as a waterproof layer.

As a background of the present invention, there is Korean Registered Patent Registration No. 0135675 (Rooftop Waterproofing Method and Rooftop Waterproofing Structure). The urethanic waterproof coating is applied to the uppermost slab and the upper part of the inner wall of the roof railing to a predetermined thickness to form a bottom waterproof layer. The field foaming urethane is applied to the outer surface of the bottom waterproof layer to a predetermined thickness to form an integral heat insulating layer The nonwoven fabric is distributed at a predetermined position on the upper surface of the integral heat insulating layer and an urethane waterproof coating is applied so that only the upper surfaces of the peripheral portions of the nonwoven fabric overlap with each other to form an adiabatic protective waterproof layer, So as to form a waterproof structure protective layer.

Therefore, the penetration of water through the gap between the heat insulating plates is thoroughly blocked, so that the waterproofing and heat insulating performance are greatly improved as a whole, and the material separation phenomenon due to temperature expansion and contraction is prevented.

However, the above background technology tends to cause air bubbles in the heat insulating layer formed of the field foamed urethane resin after the construction, and as a result, the waterproof layer may become difficult to protect due to breakage.

Korean Registered Patent Registration No. 10-0361582 (Floor structure and method for waterproof insulation) Korean Registered Patent No. 10-0474799 (Heat insulation / waterproof repair method for building roof)

The present invention relates to a roofing material for energy saving, prevention of condensation formation, prevention of damage to a waterproof layer, durability of a waterproof layer is increased, ability to cope with shrinkage and expansion behavior of a concrete base surface, And a method of constructing the same.

According to a preferred embodiment of the present invention, the roof-

A heat insulating layer made of a heat insulating material adhered to a roof concrete floor of a rooftop and made of any one of polyester foam, polyurethane foam and polystyrene foam;

A film heat insulating layer having an aluminum film adhered on an upper surface of the heat insulating layer;

A rubber waterproofing layer adhered to the surface of the film heat insulating layer by an improved asphalt injection type sheet;

A reinforcing layer attached to the surface of the rubber waterproof layer as a nonwoven fabric;

And a urethane waterproof layer coated with urethane on the surface of the reinforcing layer.

In order to prevent cracks in the joints of the modified asphalt injection sheet, a reinforcing net made of glass fiber or carbon fiber is laid on the upper surface of the joint of the modified asphalt injection sheet, and a reinforcement seal joint layer Is formed on the surface of the substrate.

Also, the present invention relates to a Urethane waterproofing layer comprising: a silica-based layer coated on a top surface of a urethane waterproof layer with silica to prevent slippage;

And a urethane top coating is formed on the upper surface to prevent discoloration of the silica sand layer.

Further, a roof-and-roof adiabatic waterproofing method according to a preferred embodiment of the present invention,

Attaching a heat insulating material made of any one of a polyester foam, a polyurethane foam and a polystyrene foam to form a heat insulating layer on a concrete floor of a roof building;

Attaching an aluminum film to form a film insulating layer on the upper surface of the heat insulating layer;

Adhering the modified asphalt-formable sheet to form a rubber waterproof layer on the surface of the film thermal insulation layer;

Attaching a nonwoven fabric to form a reinforcing layer on the surface of the rubber waterproof layer;

In order to form a reinforcement seal joint layer at the joint of the modified asphalt injection sheet, a reinforcing net made of glass fiber or carbon fiber is laid on the upper surface of the joint of the modified asphalt injection sheet and urethane is applied to the reinforcement net Wow;

Applying urethane to form a urethane waterproof layer on the surface of the nonwoven fabric;

Applying silica sand to the upper surface of the urethane waterproof layer to form a silica sand layer for preventing slip;

And a step of applying a urethane top coating to the top surface to prevent discoloration of the silica sand layer.

According to the present invention, it is possible to prevent the damage of the waterproof layer by condensation because the heat insulating layer and the film heat insulating layer excel in excellent heat insulation and have an effect of saving energy and also controlling the internal and external humidity appropriately. .

In addition, the reinforcing seal joint layer of the joint part is formed, the durability of the waterproof layer is increased, and the reinforcing layer is added to improve the ability to cope with shrinkage and expansion behavior of the concrete base surface.

Further, when the silica sand layer is applied, it has an advantage of being able to cope with fire.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments of the invention and, together with the description, serve to explain the principles of the invention, Shall not be construed as limiting.
FIG. 1 is a perspective view showing a roof-type external waterproofing structure according to the present invention. FIG.
2 is a cross-sectional view of a roof-top adiabatic waterproof structure according to the present invention.
3 is a view showing a construction procedure for obtaining a roof-top external waterproof structure according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

1 and 2, a heat insulating layer 1 is formed on a rooftop concrete floor 101 of a rooftop building 100. The insulating layer 1 may be formed of polyester foam, other polyurethane foam, polystyrene foam or the like. The thickness of the heat insulating layer 1 may be in the range of 3 mm to 10 mm. The heat insulating layer (1) blocks heat transfer from the inside to the outside or from outside to inside.

A film insulating layer 2 is formed on the upper surface of the heat insulating layer 1. The film insulating layer 2 is constructed so as to block radiant heat, maintain thermal efficiency of the heat insulating layer 1, and have moisture resistance. The film insulating layer 2 has a thin film thickness of 0.05 to 0.1 mm made of a non-rusting non-ferrous metal. For example, the film warming layer 2 can be applied with the aluminum film 12.

The rubber waterproofing layer 3 is formed on the surface of the film insulating layer 2. The rubber waterproofing layer 3 may be formed, for example, by the modified asphalt injection sheet 13. The rubber waterproof layer 3 has a thickness of 1 mm to 4 mm. The modified asphalt injection sheet (13) is a modified asphalt added with SBR, SBS, APP, etc. to straight asphalt and improved the thermosensitive property and viscoelastic property. Especially, it has been given great adhesiveness for cost- It is made to be able to work without heat or torch because one side is bonded.

A reinforcing layer (4) is formed on the surface of the rubber waterproof layer (3). The reinforcing layer (4) protects and reinforces the rubber waterproofing layer (3). The reinforcing layer 4 may be made of a fibrous sheet, for example, using a nonwoven fabric 14.

The urethane waterproof layer 6 coated with urethane is formed on the surface of the reinforcing layer 4. The thickness of the urethane waterproof layer 6 may be 2 mm to 3 mm.

On the other hand, it is preferable that a reinforcing seal bonding layer 5 is formed in the rubber waterproofing layer 3 in order to prevent cracks in the joint of the modified asphalt injection sheet 13. The reinforcing seal joint layer (5) is formed to have a constant width along the upper surface joint of the modified asphalt injection sheet (13). The reinforcing seal bonding layer 5 is formed by laying a reinforcing net 15a made of glass fiber or carbon fiber and applying urethane 15b to the reinforcing net 15a.

The upper surface of the urethane waterproof layer 6 may be formed with a silica sand layer 7 coated with silica sand to prevent slippage and to prevent discoloration of the silica sand layer 7 by a urethane top coating 9 ).

An embodiment of a construction method for obtaining an external heat and waterproof structure of the roof structure will be described with reference to FIG.

First, a heat insulating material 11 made of a polyester foam is attached (S10) in order to form a heat insulating layer 1 on a rooftop concrete bottom surface 101 of a rooftop building 100. At this time, an adhesive for insulation, a vinyl acetate-based adhesive, an acrylic-based adhesive, and a synthetic rubber adhesive may be used for adhering the heat insulating material 11.

Next, the aluminum film 12 is attached (S11) in order to form the film insulating layer 2 on the upper surface of the heat insulating layer 1. Then,

Then, the modified asphalt-formable sheet 13 is adhered (S12) in order to form the rubber waterproofing layer 3 on the surface of the film heat insulating layer 2. At this time, the release member attached to one surface of the modified asphalt injection sheet 13 is removed and then adhered.

Then, the nonwoven fabric 14 is attached (S13) in order to form the reinforcing layer 4 on the surface of the rubber waterproof layer 3.

Next, in order to form the reinforcing seal bonding layer 5 at the joint portion of the modified asphalt injection sheet 13, a reinforcing net (not shown) made of glass fiber is formed on the upper surface of the joint portion of the modified asphalt injection type sheet 13 15a are laid (S14), and urethane 15b is applied to the reinforcing net 15a. At this time, the urethane 15b enters the mesh of the reinforcing net 15a to remove the joint, and the reinforcing net 15a performs reinforcement so that cracks do not occur in the joint.

Then, urethane is applied (S15) in order to form the urethane waterproof layer 6 on the surface of the nonwoven fabric 14. At this time, urethane coating can be carried out in two divided cycles. That is, after the curing period of about one day after the first application, it is possible to proceed to the second application.

Then, silica sand is sprayed (S16) on the upper surface of the urethane waterproof layer 6 to form the silica sand layer 7 to prevent slipping. The silica sand may be selected from No. 4 to No. 7.

Finally, a urethane top coating 9 is applied on the top surface (S17) to prevent discoloration of the silica sand layer 7. At this time, 0.3 당 per 1 ㎡ of the urethane topcoat is coated to a thickness of 30 탆 or more.

The roof-top external waterproofing layer structure constructed in this way is excellent in heat insulation by the insulating layer 1 and the film insulating layer 2, and not only has an effect of reducing energy, but also appropriately controls the internal and external humidity. It is possible to prevent the damage of the waterproof layer, thereby increasing the waterproof effect of the rubber waterproof layer.

In addition, the reinforcing seal joint layer 5 of the joint part is formed to increase the durability of the waterproof layer and to provide a reinforcing layer to cope with shrinkage, expansion, and behavior of the concrete base surface. The heat insulating layer .

In addition, when the silica sand layer is applied, it is possible to cope with fire prevention.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the above teachings. will be. The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

1: insulating layer
2: Film insulation layer
3: rubber waterproof layer
4: reinforced layer
5: reinforcement seal joint layer
15a: reinforcement net
15b: Urethane
6: Urethane waterproof layer
7: Silica layer

Claims (4)

A heat insulating layer (1) made of a heat insulating material (11) made of a polyester foam, a polyurethane foam or a polystyrene foam and adhered to a roof concrete floor of a roof building;
A heat insulating layer (2) having an aluminum film (12) adhered on the upper surface of the heat insulating layer (1);
A rubber waterproofing layer (3) adhered to the surface of the film insulating layer (2) with an improved asphalt formation sheet (13);
A reinforcing layer (4) attached to the surface of the rubber waterproof layer (3) with a nonwoven fabric (14);
And a urethane waterproof layer (6) coated with urethane on the surface of the reinforcing layer (4). The method according to claim 1,
A reinforcing net 15a made of glass fiber or carbon fiber is laid on the upper surface of the joint of the modified asphalt injection sheet 13 in order to prevent cracks in the joint of the modified asphalt injection sheet 13, (15) formed by applying a urethane (15b) to the reinforcing seal joint layer (15a). The method according to claim 1,
A silica layer (7) applied on the upper surface of the urethane waterproof layer (6) by a sandpaper to prevent slippage;
Characterized in that a urethane top coating (9) is provided on the top surface to prevent discoloration of the silica sand layer (7). Attaching a heat insulating material (11) made of a polyester foam, a polyurethane foam or a polystyrene foam to form a heat insulating layer (1) on a concrete floor of a roof building;
Attaching an aluminum film (12) to form a film insulating layer (2) on the upper surface of the heat insulating layer (1);
Adhering the modified asphalt-formable sheet (13) to form a rubber waterproofing layer (3) on the surface of the film insulating layer (2);
Attaching the nonwoven fabric (14) to form a reinforcing layer (4) on the surface of the rubber waterproof layer (3);
A reinforcing net 15a made of glass fiber or carbon fiber is formed on the upper surface of the joint of the modified asphalt injection sheet 13 in order to form the reinforcing seal bonding layer 5 at the joint of the modified asphalt injection sheet 13, And applying urethane 15b to the reinforcing net 15a;
Applying urethane to form a urethane waterproofing layer (6) on the surface of the nonwoven fabric (14);
Applying silica sand on the upper surface of the urethane waterproofing layer 6 to form a silica sand layer 7 for preventing slip;
And a step of applying a urethane top coating (9) on the top surface to prevent discoloration of the silica sand layer (7).

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