KR101360132B1 - Waterproofing method of exterior-waterproof or top-down construction section of underground structure - Google Patents

Abstract

The present invention relates to a waterproofing method for an outer wall and a top-down construction section of an underground structure and more specifically, to a waterproofing method which forms an underground upper structure by installing an insulating and waterproofing sheet and a protection plate on the surface of soil startum, an earth-flow plate or a concrete surface, and then placing concrete or a structure on the insulating and waterproofing sheet and the protection plate; and a waterproofing layer on the lower part of the underground upper structure by making a low viscosity mastic seal to be pushed out to the upper part of the protection plate when the protection plate is pressed by the pressure of the underground upper structure. The waterproofing method according to the present invention is provided to protect the waterproofing layer formed on the lower side of the underground upper structure which comes in contact with the upper side of an underground lower structure even when ground subsidence, concrete cracking and displacement caused by ground deformation occur, and to perfectly prevent water leakage from the underground upper structure by easily separating the insulating and waterproofing sheet from an underground lower structure on which an insulating and waterproofing sheet is disposed.

Description

{Waterproofing Method Of Exterior-Waterproof or Top-Down Construction Section of Underground Structure}

The present invention relates to a waterproof construction method of the outer water and reverse casting section of the underground structure, in detail the present invention is to install an insulating waterproof sheet and a protective plate on the earth surface, earth plate or concrete surface, and then cast concrete or the structure thereon Forming an underground superstructure, but the protection plate is pressed by the pressure of the underground superstructure, the low-viscosity mastic seal is configured to be pushed out to the upper portion of the protective plate to the waterproof construction method to form a waterproof layer under the underground upper structure will be. According to the present invention, even when settlement, ground cracking, or behavior due to soil deformation occurs, the waterproof layer formed on the lower surface of the upper structure that is in contact with the upper part of the underground substructure is protected while the insulating waterproof sheet installed on the substructure is easily separated. Leakage of superstructure can be completely prevented.

In the situation where land is absolutely insufficient due to urbanization and population density increase, construction of underground structures for efficient use of land is rapidly increasing, and various construction methods for construction of underground structures have been developed and applied.

In particular, various efforts are being made to minimize damage to surrounding buildings and to reduce noise and vibration in the construction of urban areas with high building density. Therefore, in the underground section construction of the building, the construction is not completed after the completion of the excavation. Top-Down method is developed and applied in parallel.

On the other hand, in the case of waterproofing construction in the section to which the reverse casting method is applied, in general, the waterproof sheet protective material for directly attaching the waterproof sheet (3) directly to the base surface (1) of the lower and the like to protect the waterproof layer (4) ), It was common to form reinforcement and concrete in the upper part to form underground structures (2) such as underground roads and underground parking lots.

However, in the case of waterproofing as described above, when concrete cracks, behavior, etc. occur, water pressure is applied between the protection plates as shown in FIG. In the end, the protection plate itself became a waterway, which caused a leak in the underground upper structure. When the lower concrete is submerged due to the ground deformation, there is no waterproof layer on the lower surface of the upper structure. Could not.

Therefore, in the present invention, as shown in FIG. 1B, even when concrete cracks and behavior occur, the leakage of the underground superstructure can be prevented and damage to the waterproof layer formed on the lower surface of the underground structure even upon settlement due to soil deformation. It was developed a reverse waterproof construction method that can be completely waterproof by allowing the waterproof layer formed on the base surface to be easily separated without giving.

In order to solve the above problems, the present invention is installed on the lower structure while protecting the waterproof layer formed on the lower surface of the upper structure in contact with the upper basement substructure, even if settlement, concrete crack, behavior, etc. due to the ground deformation occurs It is an object of the present invention to provide a waterproof construction method in which the insulating waterproof sheet is easily separated to prevent leakage of underground structures.

In order to achieve the above object, the present invention in the waterproof construction method of the outer water and reverse casting section of the underground structure, the insulating waterproof sheet installation step of installing the insulating waterproof sheet 100 on the base surface (S100); Attaching a planar compression protection plate 200a on which the plurality of planar compression protection plates 200a are attached at intervals A on the insulating waterproof sheet 100 (S200); A low viscosity mastic seal filling step (S300) for filling the low viscosity mastic seal 300a in the gap A between the planar compression protection plates 200a; A low viscosity mastic seal application step (S400) of applying a low viscosity mastic seal 300b or an adhesive on the flat compression protection plate 200a filled with the low viscosity mastic seal 300a; Non-woven fabric attaching step (S500) for attaching the nonwoven fabric 400 on the low viscosity mastic seal (300b); And an underground structure construction step (S600) of placing concrete or placing a structure on the nonwoven fabric 400 to form an underground structure 2.
In the underground structure construction step (S600), the planar compression protection plate 200a is compressed by the pressure of the underground structure 2, the low viscosity mastic filled in the gap (A) between the planar compression protection plate (200a) While the seal 300a is pushed up and down the compression protection plate 200a and mixed with the low-viscosity mastic seal 300b, the seal 300a is impregnated with the nonwoven fabric 400, and in this process, the seal 300a is naturally in contact with the upper part of the underground substructure. It provides a waterproof construction method of the outflow and reverse pouring section of the underground structure, characterized in that the waterproof layer is formed on the lower surface of the upper structure.

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The planar compression protection plate 200a is made of a void material that can be compressed by the pressure of the underground structure 2, such as a foam board, and the thickness of the planar compression protection plate 200a varies depending on the scale of the underground upper structure to be constructed. Although it is formed, it is preferably 5 to 50mm so that sufficient compression is made and at the same time the low viscosity mastic seal 300a surrounds the protective plate to form a waterproof layer.

In addition, the low-viscosity mastic seal 300b applied on the planar compression protection plate 200a is to prevent the planar compression protection plate 200a from being pushed by the pressure of concrete or underground structure 2 to be poured later. It is preferable that the thickness is 0.1-3 mm.

On the other hand, another embodiment of the present invention in the waterproof construction method of the outflow and reverse casting section of the underground structure, the lower surface of the insulating waterproof sheet 100 is installed on the lower surface of the base structure 1 is insulated Waterproof sheet installation step (S'100); A low viscosity mastic seal first application step (S'200) for applying a low viscosity mastic seal 300a on the insulating waterproof sheet 100; Attaching a hole compression protection plate (200b) to which the hole compression protection plate (200b) having a hole (H) formed in the body on the low viscosity mastic seal (300) is attached (S'300); A second viscous mastic seal applying a low viscosity mastic seal 300b or an adhesive on the hole compression protection plate 200b (S'400); Non-woven fabric attaching step (S'500) for attaching the non-woven fabric 400 on the low-viscosity mastic seal (300b), and to cast concrete or put the structure on the non-woven fabric 400 to form an underground structure (2) Underground structure construction step (S'600); including,
In the underground structure construction step (S'600), the hole compression protection plate 200b is compressed by the pressure of the underground structure 2, the low viscosity mastic through the hole (H) of the hole compression protection plate 200b While the seal 300a is pushed to the upper portion of the hole compression protection plate 200b and mixed with the low-viscosity mastic seal 300b, the seal 300a is impregnated into the nonwoven fabric 400, and in this process, the upper part is in contact with the upper part of the underground substructure. It provides a waterproof construction method of the waterproof and reverse casting section of the underground structure, characterized in that the waterproof layer is formed on the lower surface of the structure.

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The hole compression protection plate (200b) is made of a pore material compressible by the pressure of the underground structure (2), the thickness of the hole compression protection plate (200b) is variously formed depending on the size of the underground superstructure to be constructed, At the same time the pressing is made of a low viscosity mastic seal (300a) is preferably 5 ~ 50mm to surround the protective plate to form a waterproof layer.

In addition, the diameter of the hole (H) formed in the hole compression protection plate 200b is formed in various ways depending on the size of the underground upper structure to be constructed, the low viscosity mastic seal 300a when the hole compression protection plate 200b is compressed It is preferably 5 to 50mm to be smoothly pushed upward through the hole (H).

In addition, in the first low-viscosity mastic seal application step (S'200), the thickness of the low-viscosity mastic seal 300a applied on the insulating waterproof sheet 100 is formed on the upper portion of the hole compression protection plate 200b. It is formed to include an amount enough to cover a sufficient amount, preferably may be formed to a thickness of 1 ~ 10mm.

In addition, the low-viscosity mastic seal in the second application step (S'400), the low-viscosity mastic seal (300b) or the adhesive is applied on the hole compression protection plate 200b, the hole compression protection plate 200b is later poured In order to prevent being pushed by the pressure of the concrete or underground superstructure, the thickness is preferably 0.1 to 3mm.

On the other hand, the insulating waterproof sheet 100 used in the waterproof construction method of the present invention is the asphalt compound layers 120a and 120b coated on the upper and lower surfaces of the center member 110 and the center member 110, respectively, the asphalt And a release layer 130 formed on the bottom surface of the compound layer 120b, and a release paper 150 adhered to the top surface of the asphalt compound layer 120a, wherein the release paper 150 is a planar compression protection plate 200a. It is characterized in that it is removed before installation. In this case, a high adhesion layer 140 may be further applied between the asphalt compound layer 120a and the release paper 150.

In addition, if necessary, the joints 101 may be formed at both ends of the insulating waterproof sheet 100. In order to prevent leakage, the adhesive layer for adhesion between the joints and the joints may have excellent adhesion. It is preferable that the rubber or high adhesion hot melt adhesive layer 160 is formed.

In addition, the low-viscosity mastic seals (300a, 300b) used in the waterproof construction method of the present invention should have a high waterproof in a wet environment while low viscosity enough to be pushed smoothly to the upper and lower portions of the protective plate by pressing, 10 to 40% by weight of process oil, 1 to 10% by weight of asphalt modifier, 1 to 5% by weight of strength reinforcement, 1 to 10% by weight of heat reinforcement agent, 2 to 20% by weight of adhesion reinforcement agent, 10 to 30% by weight of asphalt, viscosity control 10-20 wt% of inorganic filler, 10-20 wt% of anti-flow additive, 1-10 wt% of waste tire, 0.3-5 wt% of aqueous modifier, and 1-5 wt% of adhesion promoter, and amphipathic wet cotton adhesion promoter 1 It is preferable to include ˜5% by weight.

At this time, the amphiphilic wet surface adhesion promoter is a cationic, anionic, or nonionic surfactant having both a lipophilic group and a hydrophilic group to maintain a high waterproofing property even in a wet environment, or -OH (hydroxyl group), -COOH A polar covalent bonding material containing any one of (carboxyl group) and -NH ₃ (amino group) can be used.

The waterproof construction method of the present invention by pressing the protection plate under the pressure of the underground upper structure, the low-viscosity mastic seal is pushed to the upper portion of the protection plate to form a waterproof layer under the underground upper structure, sedimentation, concrete crack, Even when a behavior occurs, the waterproof layer formed on the lower surface of the upper structure which is in contact with the upper part of the underground substructure is protected, and the insulating waterproof sheet installed on the substructure can be easily separated to completely prevent leakage of the underground upper structure.

1A and 1B are conceptual diagrams showing the underground structure leakage phenomenon 1a according to the conventional waterproof construction and the underground structure leakage blocking phenomenon 1b according to the waterproof construction of the present invention.
2, 7 is a flow chart showing each step of the waterproof construction method according to the present invention.
3 and 8 is a conceptual diagram showing the appearance of the waterproof layer when the protective plate compression in accordance with the waterproof construction of the present invention.
4A and 4B are cross-sectional views showing the structure of the insulating waterproof sheet of the present invention.
5A and 5B are conceptual views illustrating a planar compression protection plate and a construction of the present invention.
6 and 10 are cross-sectional views showing the configuration of the integrated flat compression protection plate and the integrated hole compression protection plate of the present invention.
9A and 9B are sectional views showing the structure of the hole compression protecting plate according to the present invention.

Hereinafter, with reference to the accompanying drawings, the waterproof construction method of the outward water and reverse pouring section of the underground structure according to the present invention will be described in detail.

The waterproof construction method of the present invention is a waterproof construction method of the outflow and reverse casting section of the underground structure, as shown in Figure 2, the insulating waterproof sheet installation step is installed to the bottom surface of the insulating waterproof sheet 100 against the base surface (S100); Attaching a planar compression protection plate 200a on which the plurality of planar compression protection plates 200a are attached at intervals A on the insulating waterproof sheet 100 (S200); A low viscosity mastic seal filling step (S300) for filling the low viscosity mastic seal 300a in the gap A between the planar compression protection plates 200a; A low viscosity mastic seal application step (S400) of applying a low viscosity mastic seal 300b on the flat compression protection plate 200a filled with the low viscosity mastic seal 300a; Non-woven fabric attaching step (S500) for attaching the nonwoven fabric 400 on the low viscosity mastic seal (300b); And an underground structure construction step (S600) of forming concrete or placing a structure on the nonwoven fabric 400 to form an underground structure 2.

As shown in FIG. 4A, the insulating waterproof sheet 100 used in the present invention is the asphalt compound layers 120a and 120b coated on the upper and lower surfaces of the center member 110 and the center member 110, respectively. A separation layer 130 formed on the bottom surface of the asphalt compound layer 120b, and a release paper 150 adhered to the top surface of the asphalt compound layer 120a, wherein the release paper 150 is a planar compression protection plate 200a. ) Is removed before installation. In this case, as shown in FIG. 4B, a high adhesion layer 140 may be further applied between the asphalt compound layer 120a and the release paper 150.

The core material (woven fabric, nonwoven fabric, magic, etc.) and the asphalt compound layers 120a and 120b coated on the upper and lower surfaces of the center material 110 are configured as a general waterproof sheet, and various waterproof sheets used in the related art are used. Can be.

In addition, the separation layer 130 formed on the lower portion of the asphalt compound layer 120b applied to the lower surface of the central material 100 may have a base surface, that is, a lower surface of the underground upper structure constructed thereon even when the lower structure is settled. As a function of separating the formed waterproof layer without being pulled down together, a separation layer in the form of a film, such as a silica sand layer, may be used.

The high adhesion layer 140 applied to the upper portion of the asphalt compound layer 120a applied to the upper surface of the center material 100 is for adhering the compression protection plate, and is a high adhesion material capable of adhering and fixing the compression protection plate. It is preferable to make.

In addition, joints 101 may be formed at both ends of the insulating waterproof sheet 100 to connect the insulating waterproof sheets 100 to each other, as shown in FIG. 4, to prevent leakage through the joint. Butyl rubber layer or high adhesive hot melt adhesive layer 160 for adhesion between the joint portion may be formed separately.

On the other hand, the planar compression protection plate 200a installed on the insulating waterproof sheet 100 may be formed of various void materials that can be compressed by the pressure of the underground structure 2 such as foam board, PE, PP, magic, and woven fabric. have.

As the planar compression protection plate 200a is compressed by the pressure of the underground structure 2, as shown in FIG. 3, the low viscosity mastic seal 300a filled in the gap A between the planar compression protection plates 200a is shown. ) Is pushed to the upper and lower portions of the compression protection plate (200a) and is mixed with the low viscosity mastic seal (300b) to be impregnated in the nonwoven fabric (400). Through this process, the waterproof layer is formed on the lower surface of the upper structure which is in direct contact with the upper part of the underground structure.

The thickness of the planar compression protection plate 200a is variously formed according to the size of the underground upper structure to be constructed, but sufficient compression is made and at the same time the low viscosity mastic seal 300a completely surrounds the protection plate to form a waterproof layer when the protection plate is pressed. It is desirable to be formed to a thickness of 5 ~ 50mm.

In addition, the size of the planar compression shroud used in the present invention and the gap between the planar compression shroud can be modified in various ways depending on the construction area and the size of the underground superstructure to be constructed, as an embodiment of the grid form as shown in Figure 5b It is arranged to form a gap, the protective plate width (B) can be arranged so that the interval is 10 ~ 50cm every 1m.

The low-viscosity mastic seal 300a filled in the gap A between the planar compression protection plates 200a is pushed to the upper and lower portions of the protection plate by pressing during construction of the underground structure, and directly contacts the upper structure of the underground substructure. It serves to form a waterproof layer on the lower surface.

At this time, the low-viscosity mastic seal (300a) has a low enough viscosity to be pushed out by compression and have a high waterproofing in a wet environment, a general coating waterproofing material may be used, but preferably process oil 10-40 Weight%, Asphalt modifier 1 to 10% by weight, Strength reinforcement 1 to 5% by weight, Heat reinforcing agent 1 to 10% by weight, Adhesion reinforcement 2 to 20% by weight, Asphalt 10 to 30% by weight, Mineral filler for viscosity adjustment 10 to 20% %, Flow prevention additive 10-20% by weight, waste tire 1-10% by weight, aqueous modifier 0.3-5% by weight, and adhesion promoter 1-5% by weight, and amphipathic wet cotton adhesion promoter 1-5% by weight can do.

Looking at the manufacturing method of the low-viscosity mastic seal in detail, first the asphalt modifier, strength reinforcing agent, adhesion reinforcing agent, heat reinforcing agent in the process oil between 120 ~ 180 ℃ dissolve and evenly dispersed.

When the amount of the process oils used is too high, the viscosity of the product itself is too high, the workability is inconvenient, when the amount used is high, the viscosity is lowered, the heat resistance stability and adhesion is also weakened, the waterproof material properties are lowered. In addition, the asphalt modifier may be used such as rubber or elastomer, and when the amount is small, the elasticity and durability may not be sufficiently exhibited, and when the amount is large, the workability may be deteriorated.

The strength reinforcing agent may be a synthetic resin such as polypropylene, polyethylene, polystyrene, and if the amount is small, it is difficult to expect a role as a strength reinforcing agent, and if the amount is large, the physical properties of the product is too hard to cause problems in workability. have.

In addition, the adhesion reinforcing agent may be used, such as petroleum resin, natural resin, coumarone resin, if the amount of the use is less adhesive strength with the adhered surface, if the amount is used a lot of physical properties of the product is hard to break Phenomenon occurs.

The heat-resistant reinforcing agent may be used paraffin wax, polypropylene wax, polyethylene wax, oxide wax, natural wax, etc. If the amount is small, it is difficult to exert the function of heat resistance reinforcement, if the amount is used a film is formed on the surface of the product adhered surface Adhesion and adhesion performance with the deteriorate.

Next, asphalt is uniformly dispersed by adding asphalt to the process oil mixture prepared above, and the asphalt is to exert waterproof performance and rustproof performance. When the amount is too small or too large, the effect of waterproof performance cannot be seen and fluidity and There is a problem that the durability is weakened.

Into the asphalt composition, the asphalt composition, the viscosity control inorganic filler, flow prevention additives, waste tires and aqueous modifiers are uniformly dispersed.

At this time, the inorganic filler for viscosity control may be used calcium carbonate, talc, wollastonite powder, calcined lime, etc. If the amount is small, it is difficult to exhibit the viscosity control function, if the amount is large, the fluidity of the mastic waterproofing material is reduced. As the additive for preventing the flow, it is possible to use a disintegrated stone, cellulose fiber, bentonite, silica powder, and the like. If the amount is small, the waterproofing material flows down after construction of the wall, and if the amount is large, the viscosity of the waterproofing material is too high and the elasticity is lowered. May occur.

In addition, the waste tire is excellent in miscibility and bonding with the polymer to help increase the adhesion of the coating film waterproofing material and at the same time ensure sufficient watertightness, when the amount is small, the waste tire mixing effect is reduced, when the amount is relatively high The amount of polymer can be reduced and the water tightness can be reduced. The aqueous modifier may be SBR latex, EVA emulsion, natural latex, butyl latex, chloroprene latex, etc., when the amount is small, it is difficult to expect the effect of improving the properties of the waterproofing material, when the amount is too high to increase the ductility of the product As a result, the constructability and price competitiveness are inferior.

Finally, the mastic seal composition prepared as described above may be prepared by uniformly dispersing the amphipathic adhesion promoter to prepare a low viscosity mastic seal.

The amphiphilic wet surface adhesion promoter is a cationic, anionic, or nonionic surfactant having both a lipophilic group and a hydrophilic group, or any one of -OH (hydroxyl group), -COOH (carboxyl group), and -NH ₃ (amino group). It is preferable that the polar covalent bonding material including one, and in one embodiment, polyoxyethylene alkyl ether (PAAE), polyoxy ethylene alkyl ether (PAE), sorbitan fatty acid (sorbitan fatty acid ester), polyoxyethylene alkyl ester (polyoxyethylene) Alkyl Ester, Polyoxyethylene Alkyl Amine, Alkyl Ester, Alkyl Phosphates, Alkyl Sulfosuccinates, Alkyl Dimethyl benzyl Ammonium Chlorides ), Alkyl ammonium salts, dimethyl alkyl betaines, amine oxides, and the like may be used.

The molecular units of the material forming the low-viscosity mastic seal are melted and polymerized to form a large polymer mixture. When the amphipathic adhesion promoter is added to the mixture, the amphipathic adhesion promoter coats the surface of the mixture. Will be wrapped.

At this time, the polymer mixture itself is not capable of adhesion with water, but due to the large dielectric constant of the water molecule, electrostatic attraction is applied between the charged portion of the amphipathic adhesion promoter and the water molecule. The adhesive effect of pulling the mixture strongly together will appear.

Therefore, the low-viscosity mastic seal of the present invention can play a role as a semi-permanent waterproof material that does not separate from the underground structure even in an underground wet environment.

On the other hand, the low-viscosity mastic seal (300b) is applied on the planar compression protection plate 200a filled with the low-viscosity mastic seal (300a) is the pressure of the concrete or underground structure that the planar compression protection plate (200a) is to be poured later The same material or other adhesive as the low-viscosity mastic seal 300a may be used to prevent being pushed by, and the thickness thereof may be variously modified according to the size of the underground superstructure to be constructed. It may be formed to a thickness of 0.1 ~ 3mm.

The non-woven fabric 400 attached to the low-viscosity mastic seal 300b prevents the low-viscosity mastic seal from being mixed with concrete or sucked into the concrete structure without being buried on the sole when constructing an underground superstructure such as concrete placing. To this end, the mastic seal is naturally impregnated to form a waterproof layer on the lower surface of the upper structure.

In this case, the nonwoven fabric may be directly attached to the mastic seal in the field, but as shown in FIG. 6, the integral compression compressing the low-viscosity mastic seal 300b and the nonwoven fabric 400 together with the flat compression protection plate 200a. Produced protective plate 500a can also be easily installed in the field.

On the other hand, another embodiment of the waterproof construction method of the present invention is an insulating waterproof sheet installation step (S'100) is installed to the bottom surface of the insulating waterproof sheet 100 to the base surface as shown in Figure 7; A low viscosity mastic seal first application step (S'200) for applying a low viscosity mastic seal 300a on the insulating waterproof sheet 100; Attaching a hole compression protection plate (200b) to which the hole compression protection plate (200b) having a hole (H) formed in the body on the low viscosity mastic seal (300a) is attached (S'300); A second low viscosity mastic seal coating step (S'400) for applying a low viscosity mastic seal 300b on the hole compression protection plate 200b; Non-woven fabric attaching step (S'500) for attaching the non-woven fabric 400 on the low-viscosity mastic seal (300b), and to cast concrete or put the structure on the non-woven fabric 400 to form an underground structure (2) Underground structure construction step (S'600); consists of.

In this case, the insulating waterproof sheet 100 and the low viscosity mastic seals 300a and 300b may use the same configuration and material as in the case of using the planar compression protection plate 200a.

The hole compression protection plate 200b installed on the insulating waterproof sheet 100 may be compressed by the pressure of the underground structure 2 such as foam board, PE, PP, magic, and woven fabric, similar to the planar compression protection plate 200a. It can be made of various void materials.

However, unlike the flat compression protection plate 200a, the hole compression protection plate 200b has a hole formed in the protection plate itself, and as shown in FIG. 8, the hole compression protection plate 200b is formed by the pressure of the underground structure 2. The non-woven fabric 400 is pressed while the low-viscosity mastic seal 300a applied to the lower portion of the protection plate is pushed to the upper portion of the hole compression protection plate 200b through the hole H and mixed with the low-viscosity mastic seal 300b. It is impregnated to, and through this process, a waterproof layer is formed on the lower surface of the upper structure that is in direct contact with the upper part of the underground substructure.

Although the thickness of the hole compression protection plate 200b is variously formed according to the size of the underground upper structure to be constructed, sufficient compression is made and at the same time the low viscosity mastic seal 300a completely surrounds the protection plate and forms a waterproof layer when the protection plate is compressed. It is preferable that it is 5-50 mm.

In addition, the diameter of the hole (H) formed in the hole compression protection plate 200b is formed in various ways depending on the size of the underground upper structure to be constructed, the low viscosity mastic seal 300a when the hole compression protection plate 200b is compressed It is preferably 15 to 50mm to be smoothly pushed upward through the hole (H). The shape and quantity of the hole may also be variously formed. For example, the hole may be formed in a straight line as shown in FIG. 9A, or the lower part of the hole may have a larger diameter than the upper part as shown in FIG. The plastic seal may be configured to move upward through the hole.

In addition, in the first low-viscosity mastic seal application step (S'200), the thickness of the low-viscosity mastic seal 300a applied on the insulating waterproof sheet 100 is an upper portion of the hole compression protection plate 200b used. Is formed to include an amount enough to cover a sufficient amount, preferably may be formed to a thickness of 1 ~ 10mm.

In addition, in the second low-viscosity mastic seal second application step (S'400), the low-viscosity mastic seal 300b applied on the hole compression protection plate 200b is concrete in which the hole compression protection plate 200b is poured later. B. It is to be prevented from being pushed by the pressure of the underground superstructure, and the thickness thereof may be variously modified according to the size of the underground superstructure to be constructed.

The non-woven fabric 400 attached to the low-viscosity mastic seal 300b prevents the low-viscosity mastic seal from being mixed with concrete or sucked into the concrete structure without being buried on the sole when constructing an underground superstructure such as concrete placing. To this end, the mastic seal is naturally impregnated to form a waterproof layer on the lower surface of the upper structure.

In this case, the nonwoven fabric may be directly attached to the mastic seal in the field, but as shown in FIG. 10, the integral compression compressing the low viscosity mastic seal 300b and the nonwoven fabric 400 together with the hole compression protection plate 200b. Produced protective plate 500b can also be easily installed in the field.

According to the waterproof construction method of the present invention as described above, the low viscosity mastic seal is pushed to the upper part of the protection plate while the protection plate is pressed during the construction of the underground upper structure, so that a waterproof layer is formed on the lower part of the underground upper structure, settlement due to soil deformation, concrete cracking Even if a behavior occurs, the waterproof layer formed on the lower surface of the upper structure which is in contact with the upper part of the underground substructure is protected, and the insulating waterproof sheet installed on the lower structure is naturally separated to completely prevent leakage of the underground upper structure. have.

The present invention is not limited to the above-described specific embodiments and descriptions, and various modifications can be made to those skilled in the art without departing from the gist of the present invention claimed in the claims. And such modifications are within the scope of protection of the present invention.

1: base surface 2: underground structure
3: waterproof sheet 4: protective material
100: insulating waterproof sheet 101: joint
110: core material 120a, 120b: asphalt compound layer
130: separation layer 140: high adhesion layer
150: release paper 160: adhesive layer
200a: flat compression shield A: spacing between flat compression shields
200b: hole compression protective plate H: hole
300a, 300b: low viscosity mastic seal 400: nonwoven fabric
500a, 500b: Integrated compression shield

Claims (19)

In the waterproof construction method of the outflow and reverse casting section of the underground structure,
An insulating waterproof sheet installation step of installing the insulating waterproof sheet 100 on the base surface (S100);
Attaching a planar compression protection plate 200a on which the plurality of planar compression protection plates 200a are attached at intervals A on the insulating waterproof sheet 100 (S200);
A low viscosity mastic seal filling step (S300) for filling the low viscosity mastic seal 300a in the gap A between the planar compression protection plates 200a;
A low viscosity mastic seal application step (S400) of applying a low viscosity mastic seal 300b on the flat compression protection plate 200a filled with the low viscosity mastic seal 300a;
Non-woven fabric attaching step (S500) for attaching the nonwoven fabric 400 on the low viscosity mastic seal (300b); And
Includes; underground structure construction step (S600) to form concrete on the non-woven fabric 400 or to place the structure (2);
In the underground structure construction step (S600), the planar compression protection plate 200a is compressed by the pressure of the underground structure 2, the low viscosity mastic filled in the gap (A) between the planar compression protection plate (200a) Seal 300a is pushed to the upper and lower portions of the compression protection plate 200a and at the same time mixed with the low-viscosity mastic seal (300b) and the water outflow and reverse pouring section of the underground structure, characterized in that impregnated in the nonwoven fabric 400 Waterproof construction method. delete The method of claim 1,
The planar compression protection plate (200a) is made of a pore material squeezable by the pressure of the underground structure (2), the thickness of the waterproof construction method of the waterproof and reverse casting section of the underground structure, characterized in that the thickness of 5 ~ 50mm. The method of claim 1,
Low-viscosity mastic seal (300b) applied on the planar compression protection plate (200a) is characterized in that the thickness of 0.1 ~ 3mm waterproof construction method of the waterproof and reverse casting section of the underground structure. The method of claim 1,
The insulating waterproof sheet 100 is formed on the lower surface of the asphalt compound layers 120a and 120b and the asphalt compound layer 120b respectively applied to the upper and lower surfaces of the center member 110 and the center member 110. And a release paper 150 adhered to an upper surface of the separation layer 130 and the asphalt compound layer 120a, wherein the release paper 150 is removed before installation of the planar compression protection plate 200a. Waterproofing method of outflow and reverse pouring section 6. The method of claim 5,
Waterproofing method of the waterproofing and reverse casting section of the underground structure, characterized in that the high adhesion layer 140 is applied between the asphalt compound layer (120a) and the release paper 150. 6. The method of claim 5,
Joints 101 are formed at both ends of the insulating waterproof sheet 100, and an adhesive layer 160 for adhesion between the joint and the joint is formed of a hot-melt adhesive layer or a butyl rubber layer. Waterproof construction method of the waterproof and reverse casting section of the underground structure characterized by. The method of claim 1,
The low viscosity mastic seals (300a, 300b) is 10 to 40% by weight of process oil, 1 to 10% by weight of asphalt modifier, 1 to 5% by weight of strength reinforcement, 1 to 10% by weight of heat reinforcing agent, 2 to 20% by weight of adhesive reinforcement %, 10-30% by weight asphalt, 10-20% by weight inorganic filler for viscosity adjustment, 10-20% by weight flow prevention additive, 1-10% by weight waste tire, 0.3-5% by weight aqueous modifier, and adhesion promoter 1-5 Weight%, and waterproof construction method of the outer water and reverse pouring section of the underground structure, characterized in that it comprises 1 to 5% by weight of amphipathic wet surface adhesion promoter. 9. The method of claim 8,
The amphiphilic wet surface adhesion promoter is a cationic, anionic, or nonionic surfactant having both a lipophilic group and a hydrophilic group, or any one of -OH (hydroxyl group), -COOH (carboxyl group), and -NH ₃ (amino group). Waterproof construction method of the outer water and reverse casting section of the underground structure, characterized in that it comprises a polar covalent bonding material containing one. In the waterproof construction method of the outflow and reverse casting section of the underground structure,
An insulating waterproof sheet installation step of installing the insulating waterproof sheet 100 on the base surface (S'100);
A low viscosity mastic seal first application step (S'200) for applying a low viscosity mastic seal 300a on the insulating waterproof sheet 100;
Attaching a hole compression protection plate (200b) to which the hole compression protection plate (200b) having a hole (H) formed in the body on the low viscosity mastic seal (300a) is attached (S'300);
A second low viscosity mastic seal coating step (S'400) for applying a low viscosity mastic seal 300b on the hole compression protection plate 200b;
Non-woven fabric attaching step (S'500) for attaching the non-woven fabric 400 on the low viscosity mastic seal (300b), and
Includes; underground structure construction step (S'600) to form concrete on the non-woven fabric 400 or to place the structure (2 ');
In the underground structure construction step (S'600), the hole compression protection plate 200b is compressed by the pressure of the underground structure 2, the low viscosity mastic through the hole (H) of the hole compression protection plate 200b The seal 300a is pushed to the upper portion of the hole compression protection plate 200b and mixed with the low-viscosity mastic seal 300b and impregnated in the nonwoven fabric 400. Waterproof construction method. delete 11. The method of claim 10,
The hole compression protective plate (200b) is made of a pore material compressible by the pressure of the underground structure (2), the thickness of the waterproof construction method of the waterproof and reverse casting section of the underground structure, characterized in that the thickness of 5 ~ 50mm. 11. The method of claim 10,
The waterproof construction method of the outflow and reverse casting section of the underground structure, characterized in that the diameter of the hole (H) formed in the hole compression protection plate (200b) is 5 ~ 50mm. 11. The method of claim 10,
In the first low viscosity mastic seal application step (S'200), the thickness of the low viscosity mastic seal 300a applied on the insulating waterproof sheet 100 is 1 ~ 10mm,
In the low-viscosity mastic seal second application step (S'400), the thickness of the low-viscosity mastic seal (300b) applied on the hole compression protection plate (200b) is 0.1 ~ 3mm of the underground structure, characterized in that Waterproofing method of waterproofing and reverse casting section. 11. The method of claim 10,
The insulating waterproof sheet 100 is formed on the lower surface of the asphalt compound layers 120a and 120b and the asphalt compound layer 120b respectively applied to the upper and lower surfaces of the center member 110 and the center member 110. Release layer 130, and a release paper 150 bonded to the upper surface of the asphalt compound layer (120a), the release paper 150 is characterized in that the base material is removed before installation of the hole compression protection plate 200b Waterproofing method of waterproofing and reverse casting section of structure. 16. The method of claim 15,
Waterproofing method of the waterproofing and reverse casting section of the underground structure, characterized in that the high adhesion layer 140 is applied between the asphalt compound layer (120a) and the release paper 150. 16. The method of claim 15,
Joints 101 are formed at both ends of the insulating waterproof sheet 100, and an adhesive layer 160 for adhesion between the joint and the joint is formed of a hot-melt adhesive layer or a butyl rubber layer. Waterproof construction method of the waterproof and reverse casting section of the underground structure characterized by. 11. The method of claim 10,
The low viscosity mastic seals (300a, 300b) is 10 to 40% by weight of process oil, 1 to 10% by weight of asphalt modifier, 1 to 5% by weight of strength reinforcement, 1 to 10% by weight of heat reinforcing agent, 2 to 20% by weight of adhesive reinforcement %, 10-30% by weight asphalt, 10-20% by weight inorganic filler for viscosity adjustment, 10-20% by weight flow prevention additive, 1-10% by weight waste tire, 0.3-5% by weight aqueous modifier, and adhesion promoter 1-5 Weight%, and waterproof construction method of the outer water and reverse pouring section of the underground structure, characterized in that it comprises 1 to 5% by weight of amphipathic wet surface adhesion promoter. 19. The method of claim 18,
The amphiphilic wet surface adhesion promoter is a cationic, anionic, or nonionic surfactant having both a lipophilic group and a hydrophilic group, or any one of -OH (hydroxyl group), -COOH (carboxyl group), and -NH ₃ (amino group). Waterproof construction method of the outer water and reverse casting section of the underground structure, characterized in that it comprises a polar covalent bonding material containing one.

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