KR101606867B1 - Method for repairing waterproofing layer on rooftop applying moisture exhaust passage - Google Patents

Abstract

The present invention relates to a method for repairing a waterproofing layer on a rooftop applying a moisture guide path. The present invention comprises: a moisture guide path forming step of partially scraping the floor of the rooftop and constructing the moisture guide path to have a depth for accepting the moisture, confined in the lower part of an insulation layer, into the internal space of the moisture guide path; a moisture guide member setting step of arranging a moisture guide member into the internal space of the moisture guide path; an air vent installation step of installing air vents, communicating with the internal space of the moisture guide path, on the moisture guide path; and a finishing layer construction step of stacking a finishing layer on the floor of the rooftop after the air vent installation step is completed. The method for repairing a waterproofing layer on a rooftop applying a moisture guide path, having the above-described configuration, forms the moisture guide path, extended in a longitudinal direction, on the floor of the rooftop and installs the air vents on the upper part of the moisture guide path to horizontally move the moisture, distributed on the overall surface of the rooftop, via the moisture guide path and then discharge the moisture, thereby having excellent moisture removing efficiency and being capable of rapidly removing the moisture as much. In addition, the present invention scraps only a part of the floor for forming the moisture guide path without scraping all the floor of the rooftop, thereby preventing a construction size from growing larger, and accordingly maximizing reduction of the number of air vents as well as drastically lowering construction costs.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a roofing waterproofing layer,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a roof waterproofing layer repairing method using a moisture induction furnace.

Among various waterproofing methods used for waterproofing the roof of a building, the coating waterproofing method is a construction method in which a liquid waterproofing agent is applied on the floor of the roof to form a waterproof coating of a certain thickness. This is because the waterproofing agent is applied in a liquid state, it is suitable for construction of complicated part and it is possible to construct seamlessly. In addition, the interlaminar adhesion between the waterproofing agent and the mortar layer, which is the floor of the roof, is good.

However, since the coating film waterproof layer is applied to the surface of the mortar layer in a close contact manner, it can easily peel off or tear due to cracking or deformation of the mortar layer. If the waterproof layer is torn, it will no longer function as a waterproofing, and rainwater will be evenly absorbed into the mortar layer and the insulation layer below it.

In addition, the water contained in the mortar layer or the insulating layer is evaporated and expanded in the summer, and the waterproof layer is swollen from the mortar layer (for example, from the beginning when the building is newly built or since the water has permeated into the cracks of the waterproof layer) In some cases, the waterproof layer is ruptured, and in winter, sea water and ice are repeated to accelerate the breakage of the mortar layer.

In order to solve the above-mentioned problem, conventionally, a hole penetrating the mortar layer is formed at a crack part of the roof bottom, that is, a place where water is to be accumulated in the lower part thereof, and an air vent is provided in the hole.

The de-base is a passage for opening the space below the mortar layer to the atmosphere. That is, it is a means for extracting the moisture trapped in the mortar layer or the heat insulating layer to the outside.

There are various kinds of such de-base, among which, for example, Korean Patent Registration No. 10-1306620 (slim de-base) has been proposed. The slim type debris base has a structure of a support plate having a penetration portion formed at a central portion thereof, a moisture-proof film provided at the central portion, and a cover plate covering the upper portion of the support plate.

However, the conventional de-base including the above-mentioned slim de-base has a disadvantage that its cover area is limited. In other words, it is only possible to remove moisture in the local part as a de-base. The reason for this is that the water accumulated in the lower part of the insulating layer does not spread widely without being cut in a plane, but is scattered rarely.

However, it is not possible to install de-infrastructures at all points where water is expected to accumulate. If you do so, the rooftop floor will be filled with debris and will lose its function. As a result, the conventional de-molding only has a limitation in effectively removing moisture distributed over the entire surface of the roof.

The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a moisture induction furnace which is formed on a rooftop floor and which has a longitudinally extending moisture induction furnace, The present invention is directed to a roof waterproofing layer repairing method using a moisture induction furnace which is capable of removing moisture quickly as much as possible by removing moisture through a debris foundation after moving in a horizontal direction.

In addition, since the present invention does not entirely remove all of the rooftop bottom but only the portion for forming the moisture induction furnace is removed, the construction scale is not increased, the construction cost can be significantly lowered, The present invention provides a roof waterproofing layer repair method using a moisture induction furnace.

To achieve the above object, a roof waterproofing layer repairing method using a moisture induction furnace according to the present invention is a method for repairing a damaged part of a roof top floor of a building including a mortar layer and a heat insulating layer, A rooftop floor cleaning step of removing and cleaning the obstacle of the roof; After completion of the roof top floor cleaning step, the mortar layer and the heat insulating layer of the roof top floor to be repaired are crushed and rolled off to form a moisture induction furnace having a depth capable of receiving the moisture trapped in the lower portion of the heat insulating layer as its internal space An induction furnace forming step; A moisture inducing member setting step of disposing a moisture inducing member in an internal space of the moisture induction furnace formed to open upward through the moisture inducing path forming step; Filling the upper portion of the moisture-inducing member with a backfill layer after completing the moisture-inducing member setting step to eliminate a step between the moisture guide path and the roof bottom surface; A debris foundation which communicates with the inner space of the moisture guide path and horizontally moves along the moisture guide path to pass through the inside of the moisture guide path to the atmosphere, Installation steps; And a finish layer forming step of forming a finish layer on the rooftop bottom surface after the de-based mounting step is completed.

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The moisture induction space forming step may include a step of forming a moisture induction space part having a depth equal to that of the moisture induction path and forming a moisture induction space part including an upper end of a drain pipe installed on the roof, Wherein the moisture induction furnace forming step includes the step of connecting the moisture induction furnace to the moisture inducing space portion.

The moisture-inducing member may include: And a guide passage guiding the moisture to flow along the longitudinal direction of the moisture guide path and guiding the flow of moisture to the bottom surface of the guide path in contact with the bottom and the inner wall of the moisture guide path.

In addition, the moisture guiding path constitutes a horizontal closed circuit, and two or more of the debris bases are installed.

The roof waterproofing layer repairing method using the moisture induction furnace according to the present invention as described above is characterized in that a moisture induction furnace extending in the longitudinal direction is formed on the roof top floor and a debris foundation is connected to the moisture induction furnace, Is moved in the horizontal direction through the moisture guide path and then exhausted through the debris foundation, so that the water removal efficiency is excellent and the moisture can be removed as quickly as possible.

In addition, since the present invention does not entirely remove all of the roof top floor, but only the portion for forming the moisture induction furnace is removed, the construction scale is not increased and the construction unit cost can be remarkably reduced accordingly. Can be reduced.

1 is a block diagram for explaining a roof waterproofing layer repairing method to which a moisture induction furnace according to an embodiment of the present invention is applied.
2 is a perspective view showing a state in which a moisture induction furnace is formed on a roof top in a roof waterproofing layer repairing method using a moisture induction furnace according to an embodiment of the present invention.
3A and 3B are partial perspective views showing, by way of example, a moisture inducing member which can be installed in the moisture guiding path shown in FIG.
4 to 6 are views for explaining a part of the process of the roof waterproofing layer repairing method according to an embodiment of the present invention.
7 is a side cross-sectional view for explaining a dehumidification action of a moisture induction furnace, a moisture inducing member, and a deck in the roof waterproofing layer repairing method according to an embodiment of the present invention.
8 is a view showing a state immediately before a finish layer construction step in a roof waterproofing layer repairing method to which a moisture induction furnace according to an embodiment of the present invention is applied.
FIG. 9 is a cross-sectional view showing a laminated structure of a waterproof layer after completion of a roof waterproofing layer repair method using a moisture guide path according to an embodiment of the present invention.

Hereinafter, one embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

Basically, the roof waterproofing layer repairing method according to the present embodiment is characterized in that a moisture induction furnace is applied in order to draw moisture and moisture accumulated in the broken waterproof layer on the roof top, horizontally move it, and then induce and discharge it into the air.

The moisture induction furnace is a horizontal air passage installed inside the waterproofing layer. The moisture induction furnace horizontally guards the moisture leaking into the moisture induction furnace and raises it to the debris base. The moisture induction furnace is a trench-type groove formed by cutting a part of the roof top to a certain width and depth, but also to the waterproof layer as well as the mortar layer.

The thickness of the mortar layer and the waterproof layer is exposed to the both side walls in the width direction of the moisture guide path so that the moisture permeable to the waterproof layer or penetrating into the bottom of the waterproof layer flows out very quickly into the moisture guide path.

The moisture guide path may be formed by a straight line or a curved line. Furthermore, the moisture induction furnace may be configured to meet one end and the other end of the moisture induction furnace, for example, a moisture induction furnace in the form of a closed loop. Closed loop means, for example, a shape in which a moisture guide path takes the form of a polygon, an ellipse or a circle when an observer looks down on the floor.

Also, a plurality of moisture induction furnaces may be crossed to form a checkerboard pattern or a lattice pattern.

1 is a block diagram for explaining a roof waterproofing layer repairing method to which a moisture induction furnace according to an embodiment of the present invention is applied.

As shown in the figure, the roof waterproofing layer repair method using the moisture guide path according to the present embodiment includes a roof top floor cleaning step 100, a moisture guide path forming step 102, a moisture guide space part forming step 103, An induction member setting step 104, a fill step 106, a de-based installation step 108, and a finish layer construction step 110.

First, the rooftop floor cleaning step 100 is a process of removing various obstacles on the roof to be cleaned and arranging the rooftop floor cleanly. At this time, all the watertight floors floating on the roof top are peeled off. In addition, cleaning the floor of the roof, where the cracks on the floor are mainly distributed, and so on.

When the rooftop bottom cleaning step 100 is completed, a moisture induction space forming step 103 and a moisture inducing space forming step 102 are performed.

The moisture induction furnace is a trench-shaped groove formed by crushing and ingressing the roof bottom surface to a certain width and depth. In addition, the moisture induction space is a groove formed by rounding the periphery of the drain pipe provided on the roof.

FIG. 2 is a perspective view showing one embodiment of the moisture guiding passage 13 and the moisture guiding space portion 14, and FIG. 4 is a sectional view taken along line IV-IV of FIG.

Referring to the drawings, it can be seen that a moisture guide path 13 extending in the longitudinal direction and a circular moisture guide space 14 are formed on the floor of the roof 11 of the building.

The moisture guide path 13 is a groove formed with a predetermined width and depth and is formed by breaking the mortar layer 19 and inserting the heat insulating layer 17 located under the mortar layer. The depth of the moisture guide path 13 is equal to the thickness of the mortar layer 19 and the heat insulating layer 17 since the mortar layer 19 and the heat insulating layer 17 are thus cut off.

The heat insulating material constituting the heat insulating layer 17 may be a styrofoam or a nonwoven fabric. The styrofoam retains the moisture permeated through cracks (not shown) of the mortar layer 19 inside it or passes it downward to be held between the styrofoam and the waterproof layer 33 during construction. In addition, the nonwoven fabric is faded by the permeated moisture.

The building waterproof layer 33 is a basic waterproof layer applied on the roof slab 31 when the building is expanded and contracted. Depending on the building, there may be no waterproof layer (33) at the time of construction. In this case, the bottom of the moisture induction furnace 13 or the moisture inducing space 14 becomes a roof slab 31. [

The roof waterproofing layer repairing method according to the present embodiment is applicable even when there is no waterproofing layer 33 at the time of construction.

The moisture guide space 14 is formed in the periphery of the water pipe 21 together with the moisture guide path 13. The drain pipe (21) is usually located at one corner of the roof, and is a general vertical pipe that receives the sewage generated on the roof and sends it down to the bottom of the building.

The reason why the moisture guide space 14 is formed in the vicinity of the water pipe 21 is that the water collects toward the water pipe 21 at the time of usual (for example, at the time of rainfall or rooftop cleaning) for the purpose of using the water pipe 21 This is because the probability of water permeating into the mortar layer 19 and the heat insulating layer 17 around the water pipe 21 is high.

On the other hand, the moisture induction furnace 13 can be installed in a rectangular pattern as shown in Fig. 2, but can be applied in any desired form based on the rooftop state. The shape of the moisture induction furnace 13 naturally depends on the type of breakage of the waterproof layer.

If the construction of the moisture induction passage 13 and the moisture induction space portion 14 is completed through the moisture induction passage forming step 102 and the moisture inducing space portion forming step 103 as described above, The setting step 104 is performed.

The moisture guiding member setting step 104 is a process of disposing the moisture guiding members 25 and 27 in the moisture guiding passage 13 and the moisture guiding space portion 14. That is, as shown in Fig. 5, the step of mounting the moisture guiding members 25 and 27 in the moisture guiding passage 13 and the moisture guiding space portion 14 is carried out.

The moisture guide member 25 is filled in the moisture guide passage 13 as a rod-like member extending in the longitudinal direction to guide moisture to move smoothly along the longitudinal direction of the moisture guide passage 13.

3A is a partial perspective view showing a moisture inducing member 25 installed in the moisture induction furnace 13. Fig.

As shown in Fig. 3, the moisture guide member 25 extends in the longitudinal direction and has a plurality of guide passages 25a at a lower portion thereof. The guide passage 25a is a passage formed along the longitudinal direction of the moisture guide member 25 and moves the moisture introduced into the guide passage 25a in the longitudinal direction of the moisture guide passage 13. [

In addition, a lateral passage 25b is provided in the middle of the longitudinal direction of the moisture guide member 25. The lateral passage 25b is a gap formed in a direction perpendicular to the longitudinal direction of the moisture guide member 25, and opens the guide passage 25a to the side.

The lateral passage 25b is a passage for allowing moisture or moisture exuding into the moisture guide passage 13 to enter the guide passage 25a. Moisture or moisture enters the guide passage 25a through the lateral passage 25b and joins the main stream line passing through the guide passage 25a.

The upper surface of the moisture guiding member 25 supports the back layer (35 in Fig. 6), which will be described later, as a flat supporting surface portion 25c. The backfill layer 35 is supported by the moisture-inducing member 25 as a mortar or a concrete, and is stepped on the roof bottom 23 without a step.

The moisture guide member 25 is made of rubber or synthetic resin, and is cut to a desired length if necessary.

On the other hand, the moisture guide member 27 of the type shown in FIG. The moisture guide member 27 is formed by pressing a synthetic resin plate having a predetermined thickness, and includes a horizontal support surface 27a and a protrusion 27b.

The protruding portion 27b protrudes to the lower side of the support surface portion 27a and secures the guide path 27d below the support surface portion 27a by floating the support surface portion 27a from the waterproof layer 33 at the time of construction. The guide passage 27d is a space through which moisture can pass.

The moisture guide member 27 is also cut appropriately in accordance with the shape at which the moisture guide member 27 is to be seated. For example, in order to install the moisture guide member 27 in the moisture guide space 14, the moisture guide member 27 is cut into a circular shape and the pipe hole (27c in FIG.

The moisture guide member setting step 104 is a step of setting the moisture guide members 25 and 27 cut into an appropriate size in the moisture guide path 13 and the moisture guide space 14, Process.

In particular, both side portions of the moisture guide member 25 may be disposed so as to be close to the inward wall surface of the moisture guide passage 13. The reason for this is that the discharge of the moisture is smooth because the heat insulating layer 17 and the lateral passage 25b are brought close to each other as much as possible.

If the width of the moisture guide passage 13 is wider than the width of the moisture guide member 25 and the both side portions of the moisture guide member 25 are not close to the inward wall surface depending on the situation of the site, (25) is cut in the longitudinal direction and sandwiched between the moisture guide member (25) and the inward wall surface.

When the width of the moisture guide passage 13 is twice as wide as the width of the moisture guide member 25, the moisture guide members 25 are arranged in the longitudinal direction and in parallel in the width direction.

The edge of the supporting surface portion 27a is provided so as to be as close as possible to the inward surface of the mortar layer 19 even in the case of the moisture inducing member 27 provided in the moisture inducing space portion 14. [

The moisture guide member 25 provided in the moisture guide path 13 is cut to an appropriate length, and a plurality of the moisture guide members 25 are arranged in the longitudinal direction. In particular, the connecting portions of the moisture guiding member 25 extending in the longitudinal direction are brought into close contact with each other so that the guide passage 25a of the moisture guiding member 25 is not blocked.

However, as shown in Fig. 7, when a de-molding base (41 in Fig. 7) to be described later is to be provided at a connecting portion of the moisture guiding member 25, the moisture guiding member 25 should be spaced apart.

If the moisture inducing member setting step 104 is completed through the above process, the filling step 106 is continued.

The filling step 106 is a step of filling the backflowing layer 35 on the moisture inducing members 25 and 27 to form the moisture induction path 13 and the moisture inducing space part 14, The process of filling in the inner space of FIG.

The backfill layer 35 is a mortar or a concrete, and the surface of the backfill layer 35 is not stepped from the roof bottom 23. In some cases, aggregate such as gravel or sand may be filled first in the lower part of the backfill layer 35.

Particularly, the surface of the backfill layer 35 to be filled in the moisture guide space 14 should be formed so as to be inclined downward toward the water pipe 21. Naturally, it is to smooth out the water.

In addition, the installation hole (35b in Fig. 7) should be left at the point where the descaling base 41 is to be installed. The position of the mounting hole 35b is appropriately determined according to the length and position of the moisture guide passage 13 and the moisture guide space portion 14 and distribution characteristics of water.

Through the above process, hollow guide passages 25a and 27d are provided in the roof bottom 23.

The subsequent de-based installation step (108) is a step of erecting the debris foundation (41) on the installation hole (35b) formed in the filling step (106).

7, the de-base 41 includes a vertically extending vertical pipe 41a fitted to the mounting hole 35b and a cover 41b covering the upper end of the vertical pipe 41a .

The de-base (41) receives the moisture passing through the guide passage (25a) of the moisture guiding member (25a), guides the moisture to the upper portion, and discharges the moisture to the atmosphere. The type or size of the debris base 41 can be changed as long as it can perform such a role.

8 is a perspective view of the roof bottom 23 showing the state after the de-based installation step 108 is completed.

Referring to the drawing, it is understood that the backflow layer 35 is filled in the moisture induction passage 13 and the moisture induction space portion 14. It is a matter of course that the moisture inducing members 25 and 27 are located below the backflow layer 35.

In addition, two debris bases 41 are provided in the moisture induction furnace 13. The debris 41 communicates with the moisture induction furnace 13 to suck the moisture in the moisture induction furnace 13 and discharge it to the atmosphere.

In particular, as shown in the drawing, when two (or more) debris bases 41 are installed, the moisture removal effect of the lower portion of the roof bottom 23 is more excellent. This is because the dry air in the atmosphere can enter the moisture induction furnace 13 through the debris removal base 41 when moisture is released through the debris base 41 on one side. This means that the performance of the moisture induction furnace can be greatly improved by adjusting the number of mounts and mounting positions of the de-base 41 as necessary.

The subsequent finish layer construction step 110 is a process of covering the entire surface of the roof top 23 with a finish layer 55 after the de-based installation is completed.

9, the finish layer 55 includes a lower layer 43 applied to the surface of the rooftop 23 and the back filler layer 35, The impregnated sheet layer 47, the second intermediate layer 49, the third intermediate layer 51, and the upper layer 53. The first intermediate layer 45, the impregnated sheet layer 47, the second intermediate layer 49,

The undercoat layer 43 maintains strong adhesion of the first intermediate layer 45 to the roof top 23. The undercoat layer and the first, second and third intermediate layers may be paints used in general waterproofing operations.

The impregnated sheet layer 47 is laminated on top of the first intermediate layer 45 as a high-density polyester fiber layer impregnated with an acrylate polymer waterproofing liquid. The impregnated sheet layer 47 greatly improves the durability of the completed roof waterproof layer.

When the second intermediate layer 49 and the third intermediate layer 51 are applied, the corners and corners of the roof are closed.

The upper layer 53 is a heat insulating layer made of heat-shading paint. The heat paints have a function to block the movement of heat. In this way, the thermal insulation effect of the building can be increased by finishing the finish layer 55 with heat shielding paint.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

11: Rooftop 13: Moisture induction furnace 14: Moisture inducing space part
17: insulation layer 19: mortar layer 21: drain pipe
23 rooftop bottom 25 moisture guide member 25a guide passage
25b: a side passage 25c: a support surface portion 27:
27a: Support surface portion 27b: Projection portion 27c: Pipe hole
27d: guide passage 31: rooftop slab 33: waterproof layer
35: back fill layer 35b: mounting hole 41:
41a: vertical pipe 41b: cover 43: underside layer
45: first intermediate layer 47: impregnated sheet layer 49: second intermediate layer
51: third intermediate layer 53: upper layer 55: finish layer

Claims (6)

As a method for repairing a damaged portion of a building roof top floor including a mortar layer and a heat insulating layer,
A rooftop floor cleaning step for removing and cleaning obstacles on the roof to perform maintenance work;
After completion of the roof top floor cleaning step, the mortar layer and the heat insulating layer of the roof top floor to be repaired are crushed and rolled off to form a moisture induction furnace having a depth capable of receiving the moisture trapped in the lower portion of the heat insulating layer as its internal space An induction furnace forming step;
A moisture inducing member setting step of disposing a moisture inducing member in an internal space of the moisture induction furnace formed to open upward through the moisture inducing path forming step;
Filling the upper portion of the moisture-inducing member with a backfill layer after completing the moisture-inducing member setting step to eliminate a step between the moisture guide path and the roof bottom surface;
A debris foundation which communicates with the inner space of the moisture guiding path and horizontally moves along the moisture guiding path to pass through the inside of the moisture guiding path to the atmosphere, Installation steps;
And a finish layer forming step of forming a finish layer on the roof bottom surface after the de-based installation step is completed. delete delete The method according to claim 1,
Forming a moisture induction space portion having a depth equal to the depth of the moisture induction passage and forming a moisture induction space portion including an upper end portion of a drain pipe installed in the roof on the roof, Lt; / RTI >
Wherein the moisture induction furnace forming step includes the step of connecting the moisture induction furnace to the moisture inducing space part. The method according to claim 1,
The moisture guide member comprises:
And a guide passage guiding the moisture to flow along the longitudinal direction of the moisture guide path and guiding the flow of the moisture to the bottom surface in a state of being in contact with the bottom and the inner wall of the moisture guide path. Rooftop waterproofing repair method applied. The method according to claim 1,
Wherein the moisture induction furnace constitutes a horizontal closed circuit and at least two of the debris bases are installed.

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