KR101387587B1 - Method for constructing insulated water supply for waterproofing heat storage tank - Google Patents

Abstract

The present invention relates to a heat storage tank waterproof insulation drainage construction method, and in detail, the drainage panel is installed on the side wall or bottom surface of the concrete structure in contact with the soil surface, the drainage path is formed through the drainage panel, and urethane foam on the front of the drainage panel. The present invention relates to a heat storage tank waterproof insulation drainage construction method to sequentially apply polyurea and polyurea.

Description

Heat storage tank waterproof insulation drainage construction method {METHOD FOR CONSTRUCTING INSULATED WATER SUPPLY FOR WATERPROOFING HEAT STORAGE TANK}

The present invention relates to a heat storage tank waterproof insulation drainage construction method, and in detail, the drainage panel is installed on the side wall or bottom surface of the concrete structure in contact with the soil surface, the drainage path is formed through the drainage panel, and urethane foam on the front of the drainage panel. The present invention relates to a heat storage tank waterproof insulation drainage construction method to sequentially apply polyurea and polyurea.

Generally, heat storage tanks (ice heat storage tanks and shrinkage heat tanks) installed in a machine room of a building are facilities for cooling buildings, and are a system for supplying cold and cold water at a necessary time while keeping a cooling medium at a low temperature for a predetermined time.

The heat storage tank usually has a structure of concrete, and a large amount of water (shrink heat tank) or brine & capsule (ice heat storage tank) is filled in the volume of the heat storage tank constituting the structure.

The cooling of the heat storage medium (capsules or water) filled in the heat storage tank is mainly performed by cooling the refrigerator by operating the freezer at a low-night time when electricity bills are low, and circulation of water or brine maintaining a low temperature from the heat storage tank in the morning and afternoon hours. Cold air is supplied to the air duct for each floor to cool the room in a comfortable state.

According to the cooling of the capsule, the inside of the ice storage tank maintains almost freezing state, and then the cooling is activated. In the afternoon time after a certain time, the refrigerant rises again above the set temperature, and the brine in the storage tank is cooled again in the midnight time zone. It allows for repeated cycles.

The construction of the heat storage tank requires a waterproofing process made by a plurality of process treatments on the inner wall surface thereof, and has the following conditions.

Form the concrete structure by installing the formwork for casting concrete, but check or measure whether there is no moisture in the structure for curing period, and also check whether there is a weak part in the structure.

Waterproof construction in the state as described above is disclosed in Korea Patent Publication No. 10-2007-0092046 (waterproof construction method of the heat storage tank).

The waterproof construction method of the heat storage tank, as shown in Figure 1, to flatten the inner wall and the bottom surface of the concrete structure 20a constituting the heat storage tank 20 to form a base adjustment layer, the base adjustment layer formed in the step Laminating the urethane foam 23 which is a heat insulating material on the upper surface, and applying the urethane waterproofing agent 24 on the urethane foam 23 laminated in the above step, and on the urethane waterproofing agent 24 applied in the step Attaching the interior film 25 and applying the polyurea 26, which is a finish waterproofing material, on the interior film 25 attached in the step.

However, the waterproof construction method of the conventional heat storage tank has a problem that the heat insulation performance of the urethane foam is deteriorated when water is introduced through the earth surface when the concrete structure is interviewed with the earth surface.

In addition, since urethane foam and polyurea are applied only once, there is a problem in that the waterproofing and thermal insulation performance is immediately degraded when the urethane foam and the polyurea are broken.

Korean Patent Publication No. 10-2007-0092046

The present invention is to solve the above problems, by installing a drainage panel on the side wall or the bottom surface of the concrete structure in contact with the soil surface, and by forming a drainage through the drainage panel water through the soil surface and the concrete structure into the heat storage tank It is an object of the present invention to provide a heat storage tank waterproof insulation drainage construction method that can prevent the inflow of the urethane foam to prevent degradation of the thermal insulation performance in advance.

In addition, the present invention by applying the urethane foam and polyurea in the second order sequentially on the front of the drain panel, even if any one of the urethane foam and polyurea is damaged, the heat storage tank waterproof to maintain the waterproof insulation performance with the remaining urethane foam and polyurea It is an object of the present invention to provide an adiabatic drainage construction method.

According to an aspect of the present invention,

In the heat storage tank waterproof insulation drainage construction method in which one side wall or bottom surface or one side wall and the bottom surface of the heat storage tank which are the soil surface and the concrete structure are interviewed, a drainage panel is provided on the inner surface of the concrete structure which is the part which is interviewed with the soil surface. Drainage panel installation process for installing a; Forming a primary heat insulation layer by foaming urethane foam on the front surface of the drainage panel; Forming a primary polyurea layer by applying polyurea to the entire surface of the primary heat insulation layer to form a primary polyurea layer; Forming a secondary heat insulation layer by foaming urethane foam on the entire surface of the primary polyurea layer; And a secondary polyurea layer forming process of applying polyurea to the entire surface of the secondary heat insulation layer to form a secondary polyurea layer.

Here, the drain panel installation process forms a drain pipe and a drain trap associated with the drain panel.

Here, the drain panel is formed of a metal or a synthetic resin material.

Here, the drainage panel is formed on the back of the drainage guide is arranged in one direction.

Here, the drain panel is formed in a continuous concave-convex shape so that the drain guide is formed.

Here, the drainage panel is fixedly installed by the anchor bolt when installed on the side wall.

Here, the drainage panel is fixed by its own weight when installed on the bottom surface, and the reinforcing rootless mortar on the upper surface, and the primary heat insulation layer, the primary polyurea layer and the upper surface of the reinforcing rootless mortar , The secondary heat insulation layer and the secondary polyurea layer are sequentially formed.

Here, the drainage panel is fixed by its own weight when installed on the bottom surface, the reinforcing rootless mortar on the upper surface, the primary heat insulation layer, the primary polyurea layer and After forming the secondary heat insulation layer, the rootless mortar for secondary reinforcement is poured on the upper surface of the secondary heat insulation layer, and a primer or urethane waterproofing modifier is applied to the upper surface of the rootless mortar for secondary reinforcement to form the secondary polyurea layer.

According to the heat storage tank waterproof insulation drainage construction method of the present invention configured as described above, by installing a drainage panel on the side wall or bottom surface of the concrete structure in contact with the soil surface, by forming a drainage through the drainage panel through the heat storage tank and the concrete structure It is possible to prevent the deterioration of the thermal insulation performance of the urethane foam by blocking the inflow of water into the interior.

In addition, according to the present invention by urethane foam and polyurea sequentially applied to the front of the drainage panel in a second, even if any one of the urethane foam and polyurea is damaged can maintain the waterproof insulation performance with the remaining urethane foam and polyurea.

1 is a view showing a waterproof construction method of a conventional heat storage tank.
2 is a process chart for explaining a heat storage tank waterproof insulation drainage construction method according to the present invention.
3 is a partial cross-sectional perspective view showing a side wall to which the heat storage tank waterproof insulation drainage construction method according to the present invention is applied.
4 and 5 is a partial cross-sectional perspective view showing a bottom surface to which the heat storage tank waterproof insulation drainage construction method according to the present invention is applied.
6 and 7 are perspective views showing the configuration of the drain panel according to the heat storage tank waterproof insulation drainage construction method according to the present invention.

Hereinafter, the heat storage tank waterproof insulation drainage construction method according to the present invention will be described in detail with reference to the accompanying drawings.

In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intentions or customs of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification.

2 is a process chart for explaining a heat storage tank waterproof insulation drainage construction method according to the invention, Figure 3 is a partial cross-sectional perspective view showing a side wall to which the heat storage tank waterproof insulation drainage construction method according to the present invention, Figures 4 and 5 Partial cross-sectional perspective view showing a bottom surface to which the heat storage tank waterproof insulation drainage construction method according to the invention is applied, Figures 6 and 7 are perspective views showing the configuration of the drain panel according to the heat storage tank waterproof insulation drainage construction method according to the present invention.

2 to 7, the heat storage tank waterproof insulation drainage construction method according to the present invention includes a drainage panel installation process (S100), a primary insulation layer formation process (S110), a primary polyurea layer formation process (S120) and , A secondary heat insulation layer forming step (S130), and a secondary polyurea layer forming step (S140).

<< drainage panel installation process-S100 >>

First, the drainage panel 110 is installed on the inner side surface of the concrete structure 103, which is a part interviewed with the soil surface 101. At this time, it is preferable to preform the infiltration waterproof layer 105 on the inner surface of the concrete structure 103 and the tar epoxy waterproof layer 107 on the front surface of the infiltration waterproof layer 105 before installation of the drainage panel 110. At this time, it is preferable to install a finishing material such as silicon or a backup material between the drainage panel 110 and the neighboring drainage panel 110.

On the other hand, the drainage panel 110 is formed of a metal or synthetic resin material (PDF material) having a thickness of 30 ~ 50㎜, as shown in Figure 6 drainage guide 111 is formed in one direction on the back surface is formed or Figure 7 As shown in FIG. 1, the drain guide 111 may be formed in a continuous uneven shape.

In addition, when the drainage panel 110 is installed on the side wall, it is fixedly installed by the anchor bolt 120 as shown in FIG. 3, and when it is installed on the bottom surface, as shown in FIGS. 4 and 5 by self weight. Fixed, the reinforcement rootless mortar 130 is poured into a thickness of 40 ~ 60㎜ to withstand the load on the upper surface, drain pipe 140 and drain trap 150 associated with the drain guide 111 of the drain panel 110 ).

In addition, when the drainage panel 110 is installed on the side wall, the drainage guide 111 is installed to be perpendicular to the ground so that drainage occurs, and when the drainage panel 110 is installed on both the sidewall and the bottom surface, it is installed on the sidewall. It is preferable to install the drainage guide 111 of the drainage panel 110 and the drainage guide 111 of the drainage panel 110 installed on the bottom in the same line to drain the water.

《Primary Insulation Layer Forming Process-S110》

When the installation of the drainage panel 110 is completed, the primary insulation layer 160 is formed by foaming urethane foam on the front surface of the drainage panel 110. At this time, since the thickness of the primary heat insulation layer 160 forms the heat insulation layer twice, it is preferable that it is formed in 30-40 mm which is 1/2 of the thickness of a general heat insulation layer. In addition, when the drainage panel 110 is installed on the bottom surface, the primary insulating layer 160 is formed on the upper surface of the reinforcement rootless mortar 130.

<< primary polyurea layer formation process-S120 >>

Then, polyurea is applied to the entire surface of the primary heat insulation layer 160 to form the primary polyurea layer 170. At this time, the thickness of the primary polyurea layer 170 is preferably formed to 1 ~ 2mm.

《Secondary Insulation Layer Forming Process-S130》

Subsequently, urethane foam is foamed on the entire surface of the primary polyurea layer 170 to form a secondary heat insulation layer 180. At this time, since the thickness of the secondary heat insulation layer 180 forms the heat insulation layer twice, it is preferable that it is formed in 30-40 mm which is 1/2 of the thickness of a general heat insulation layer. On the other hand, when the drainage panel 110 is installed on the bottom surface as shown in Figure 6 after forming the secondary thermal insulation layer 180 to a thickness of 70 ~ 80mm to withstand the load on the upper surface of the secondary thermal insulation layer 180 After pouring the rootless mortar for secondary reinforcement (200) and then applying a primer or urethane waterproofing control material (210) on the upper surface of the secondary reinforcing rootless mortar (200).

<< 2nd polyurea layer formation process -S140 >>

Subsequently, the second polyurea layer 190 is formed by applying polyurea to the front surface of the secondary heat insulation layer 180 or the top surface of the primer or urethane waterproofing material 210 applied to the rootless mortar 200 for secondary reinforcement. do. At this time, the thickness of the secondary polyurea layer 190 is preferably formed to 1 ~ 3mm.

On the other hand, the concrete structure (not shown) of the portion that is not interviewed with the soil surface by applying a general waterproof insulation method or the primary insulation layer 160, the primary polyurea layer 170, the secondary insulation layer 180 and 2 The primary polyurea layer 190 may be applied.

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. It is to be understood, however, that the invention is not to be limited to the specific forms thereof, which are to be considered as being limited to the specific embodiments, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims. .

The heat storage tank waterproof insulation drainage construction method according to the present invention can be applied to a facility for storing fluid underground, such as a storage tank, an oil storage tank, as well as a heat storage tank.

101: soil slope 103: concrete structure
110: drain panel 111: drain guide
120: anchor bolt 140: drain pipe
150: drain trap 160: primary insulation layer
170: primary polyurea layer 180: secondary insulation layer
190: second polyurea layer

Claims (8)

In the heat storage tank waterproof insulation drainage construction method in which one side wall or the bottom surface or one side wall and the bottom surface of the heat storage tank which is the soil surface and the concrete structure are interviewed and installed,
A water-proof layer is formed on the inner surface of the concrete structure, which is a part interviewed with the soil surface, and a tar epoxy water-proof layer is formed on the front surface of the water-permeable waterproof layer. The guide is arranged or formed in a continuous concave-convex shape so that the drain guide is formed, and a drainage panel in which a drainage guide having a concave-convex shape continuous in one direction is arranged on a rear surface thereof, and a drain pipe and a drain trap connected to the drainage panel A drainage panel installation step of forming a groove;
When installed on the side wall to form a primary insulation layer by foaming urethane foam to the front of the drain panel to 30 ~ 40㎜ thickness, and when installed on the bottom surface 40 ~ 60 to withstand the load on the top surface of the drain panel Forming a primary heat insulation layer by pouring a reinforcing rootless mortar with a thickness of ㎜ and then foaming urethane foam with a thickness of 30 to 40 mm on the front surface of the reinforcing rootless mortar;
Forming a primary polyurea layer by applying polyurea to a thickness of 1 to 2 mm on the entire surface of the primary heat insulation layer to form a primary polyurea layer;
When installed on the side wall to form a secondary heat insulating layer by foaming urethane foam to the front of the primary polyurea layer with a thickness of 30 ~ 40㎜, and when installed on the bottom surface withstands the load on the upper surface of the secondary heat insulating layer Forming a secondary heat insulation layer by pouring a rootless mortar for secondary reinforcement to a thickness of 70 to 80 mm and then applying a primer or a urethane waterproofing modifier to the upper surface of the rootless mortar for secondary reinforcement; And
Heat storage tank waterproof insulation drainage construction method comprising a secondary polyurea layer forming step of forming a second polyurea layer by applying a polyurea to the front of the secondary heat insulation layer to a thickness of 1 to 3mm. delete delete delete delete The method according to claim 1,
The drain panel,
Heat storage tank waterproof insulation drainage construction method characterized in that the installation is fixed by the anchor bolt when installed on the side wall. delete delete

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