KR20120111017A - Apparatus for draining subsurface water - Google Patents

Abstract

PURPOSE: An underground water drainage system is provided to prevent dew condensation by forming an insulation space layer between an upper protection concrete layer and a footing concrete layer. CONSTITUTION: An underground water drainage system(100) comprises a drain board assembly(110), a collecting well(30), a ventilation pipe(170), and a hot air supplier(180). The drain board assembly is composed of a main drain board member(120) and an insulation drain board member(130). The main drain board member is installed between a footing concrete layer(10) and an upper protection concrete layer(20) and is composed of a first base plate and multiple first support columns. The insulation drain board member is installed on the bottom of the main drain board member and is composed of a second base plate and multiple second support columns. An insulation space layer(150) is formed between the first and second base plates. [Reference numerals] (180) Hot air supplier

Description

Groundwater drainage {apparatus for draining subsurface water}

The present invention relates to groundwater drainage, and more particularly to groundwater drainage having an insulating air layer between the upper protective concrete layer and the foundation concrete layer.

In general, the drain plate is for waterproofing for the infiltration water of the underground structure, it is installed between the base concrete and the upper protective concrete to prevent the moisture and condensation and leakage of the underground layer. These drainage plates are installed in underground structures, underground constant temperature and humidity rooms, underground bunkers, artifact exhibition rooms and storages, tunnels, subways, swimming pools, underground parking lots, electrical rooms, and machine rooms to prevent incomplete underground waterproof defects. In case of replacement, it can reduce the construction time and cost by reducing the amount of underground digging and residual soil treatment.

Korean Patent Laid-Open Publication No. 2005-0110305 discloses a drainage plate and a method of constructing a basement floor using the same. The disclosed drainage plate is formed with a plurality of support pillars protruding to one side of the plate at regular intervals, and has a configuration in which an opening is formed so that concrete is discharged to the lower end of the support pillar.

Such a drain plate forms a drainage path between the upper protective concrete layer and the foundation concrete layer, but does not provide an insulation effect between the upper protective concrete layer and the foundation concrete layer, and thus has a disadvantage in that condensation and moisture protection functions of the basement layer are deteriorated.

The present invention has been made to solve the above requirements, it is an object of the present invention to provide a groundwater drainage device that can improve the condensation and moisture protection by improving the insulating ability between the upper protective concrete layer and the base concrete layer. .

In order to achieve the above object, the groundwater drainage device according to the present invention collects the infiltration water flowing between the foundation concrete layer of the building and the upper protective concrete layer placed on the foundation concrete layer to be discharged to the sump. In the groundwater drainage device, the main drainage plate is provided between the upper protective concrete layer and the base concrete layer, and includes a first base plate and a plurality of first support pillars protruding downward from the first base plate. Absence; The second support plate is installed below the main drain plate member and has a second base plate and a plurality of second support pillars protruded downward from the second base plate so that the first support pillars can be inserted therein. The second base plate is spaced downwardly with respect to the first base plate in the state that the first support pillar is inserted in the support to the heat insulating drainage plate to form a heat insulating space layer between the first base plate Member;

According to an aspect of the present invention, the lower surface of the first support pillar and the lower surface of the second support pillar have a closed structure.

According to another aspect of the present invention, a first through hole is formed on a lower surface of the first support pillar, a second through hole is formed on a lower surface of the second support pillar, and the second support pillars are slidable. Auxiliary support pillars are inserted along the first and second support pillars by the weight of the mortar of the upper protective concrete layer which is inserted in the upper portion of the main drain plate member to contact the upper surface of the foundation concrete layer to the connection portion It is further provided with an auxiliary drainage plate connected by.

Here, it is preferable that the height of the second support pillar is higher than the height of the auxiliary support pillar, and the height of the first support pillar is higher than that of the second support pillar.

In addition, the heat insulation drainage plate member is formed so that the adjacent other heat insulation drainage plate member and the edge portion overlap each other.

In addition, a lower surface of the auxiliary support pillar is closed, and a first insulating layer laminated with a heat insulating material may be further formed below the upper protective concrete layer from the lower surface of the second support pillar to the lower surface of the first support pillar. .

The second base plate may further include a second heat insulating layer laminated with a heat insulating material to be spaced apart from the first base plate.

In addition, the upper protective concrete layer is formed to communicate from the upper surface of the upper protective concrete layer to the insulating air layer is formed in the outside air inlet so that the outside air is introduced into the insulating air layer is formed, the outside air inlet window forming area The first base plate may be formed with a vent hole that is in communication with the insulating air layer.

More preferably further includes a warm air supply for supplying warm air through the heat insulating air layer.

In addition, the connecting portion of the auxiliary drain plate is a third base plate for connecting the upper portion of the auxiliary support pillar in a mutual plate shape, and is coupled to communicate with the insulating air layer through the third base plate and the second base plate to warm air or And a ventilation pipe connected to allow the outside air to enter and exit the adiabatic air layer. The hot air supplier may be configured to supply warm air through the ventilation pipe.

According to the groundwater drainage device according to the present invention, the effect of suppressing condensation, moisture or leakage to the upper protective concrete layer by the insulating air layer formed between the upper protective concrete layer and the foundation concrete layer is improved.

1 is a cross-sectional view showing a groundwater drainage device according to a first embodiment of the present invention,
FIG. 2 is an exploded perspective view of the drain plate assembly of FIG. 1;
3 is a cross-sectional view of the coupling portion for explaining the coupling structure of the heat insulation drainage plate member of FIG.
Figure 4 is an exploded perspective view showing a drain plate assembly applied to the groundwater drainage device according to a second embodiment of the present invention,
5 is an exploded perspective view illustrating a drain plate assembly applied to the groundwater drainage apparatus according to the third embodiment of the present invention;
FIG. 6 is a cross-sectional view illustrating the groundwater drainage device to which the drainage plate assembly of FIG. 5 is applied;
FIG. 7 is a cross-sectional view illustrating a structure in which a first insulation layer is further formed in the groundwater drainage device of FIG. 6.
8 is a cross-sectional view illustrating a structure in which a second insulation layer is further formed in the groundwater drainage device of FIG. 6.
9 is a cross-sectional view illustrating a structure in which an auxiliary collecting channel is formed in the groundwater drainage device of FIG. 6;
10 is a cross-sectional view illustrating a structure in which an outside air inlet is formed in the groundwater drainage device of FIG. 6.
11 is a cross-sectional view showing a ventilation pipe coupled in communication with the adiabatic air layer of the groundwater drainage device of FIG. 6,
12 is an exploded perspective view of the drainage plate assembly for explaining the coupling structure of the ventilation pipe of FIG. 11.

Hereinafter, with reference to the accompanying drawings will be described in more detail groundwater drainage apparatus according to a preferred embodiment of the present invention.

1 is a cross-sectional view showing a groundwater drainage device according to a first embodiment of the present invention, Figure 2 is an exploded perspective view of the drainage plate assembly of FIG.

1 and 2, the groundwater drainage device 100 according to the present invention includes a drainage plate assembly 110, a sump well 30, and ventilation installed between the foundation concrete layer 10 and the upper protective concrete layer 20. A pipe 170 and a warm air supply 180 is provided.

Reference numeral 12 denotes a strata, reference numeral 13 denotes an oyster finish layer formed of xantre, gravel, or rubble, and reference numeral 14 denotes a discarded concrete layer. Of course, the structure up to the ground layer 12 below the foundation concrete layer 10 may be different from the illustrated structure.

The drainage plate assembly 110 may collect the infiltration water introduced between the foundation concrete layer 10 of the building and the upper protective concrete layer 20 placed on the foundation concrete layer 10 and discharge it to the sump 30. The main drain plate member 120 and the heat insulating drain plate member 130 are provided.

The main drain plate member 120 is installed below the upper protective concrete layer 20 between the upper protective concrete layer 20 and the foundation concrete layer 10.

The main drain plate member 120 includes a first base plate 121 having a rectangular plate shape, and a plurality of first support pillars 122 that extend from the first base plate 121 and protrude downward.

The lower surface 123 of the first support pillar 122 of the main drain plate member 120 is closed.

Unlike the illustrated example, the lower surface 123 of the first support pillar 122 of the main drain plate member 120 has a second support pillar of the heat insulation drain plate member 130 to be described later when the concrete mortar is poured for the upper protective concrete layer 20. Of course, a plurality of through holes may be formed to be introduced into the lower surface 133 of the 132 or may be formed in a completely open structure.

Here, the first support pillar 122 is formed in a tapered cylindrical shape in which both the outer diameter and the inner diameter are gradually narrower as the downwardly progresses, and may be formed in a polygonal shape unlike the illustrated example.

The insulation drainage plate member 130 is installed below the main drainage plate member 120.

The heat insulation drainage plate member 130 includes a plurality of second support pillars protruding downwardly from the second base plate 131 so that the second base plate 131 and the first support pillar 122 can be inserted thereinto. 132 has a structure.

The lower surface 133 of the second support pillar 132 of the heat insulation drainage plate member 130 is closed.

Here, the heat insulation drainage plate member 130 is spaced downward from the first base plate 121 with the second base plate 131 in the state in which the first support pillar 122 is inserted into the second support pillar 132. Thus, the insulating space layer 150 may be formed between the first base plate 121 and the first base plate 121.

In the illustrated example, the height of the first support pillar 122 is higher than that of the second support pillar 132 of the heat insulating drainage plate member 130, and thus, the first base plate 121 and the second base plate ( 131 has a structure that can secure the space apart.

In addition, the heat insulation drainage plate member 130 is preferably formed so that the adjacent other heat insulation drainage plate member 130 and the edge portion overlap each other, an example will be described with reference to FIG.

The second base plate 131 is disposed in a direction perpendicular to the main portion 131a having a rectangular plate shape and adjacent to the first surface 131b and the first surface 131b of the edge of the main portion 131a. The first portion 136 having a coupling bone 134 formed to be opened downward along the edge on the surface 131c and extended parallel to the first surface 131b opposite the first surface 131b. It is formed to have a second portion 138 formed with a coupling piece 137 to enter the coupling bone 134 at the edge of the fourth surface 131e opposite the third surface 131d and the second surface 131c. It is.

Here, the coupling bone 134 and the coupling piece 137 may be formed of a structural structure that is easily sealed by mutual coupling, and the shape is not limited.

In addition, the portion coupled by the coupling bone 134 and the coupling piece 137 is preferably finished to be sealed with a sealing material.

Ventilation pipe 170 is the main drain plate member 120 and the heat insulating drain plate member (120) so that the outside air or hot air can be supplied to the heat insulating air layer 150 formed between the main drain plate member 120 and the heat insulating drain plate member 130 ( It extends outward from the thermal insulation air layer 150 between 130.

The warm air supply 180 is installed to supply the warm air through the ventilation pipe.

The groundwater drainage device 100 sequentially laminates the insulation drainage plate member 130 and the main drainage plate member 120 on the foundation concrete layer 10, and then casts it onto the main drainage plate member 120 with concrete mortar. What is necessary is just to form (20).

In addition, the insulating air layer 150 formed between the main drain plate member 120 and the insulating drain plate member 130 has a top protective concrete by forming a heat insulating layer with air between the base concrete layer 10 and the upper protective concrete layer 20. Condensation to the layer 20, the moisture prevention effect can be increased, and when the warm air is supplied by the warm air supply 180, the condensation and moisture prevention effect is further improved.

Meanwhile, the drainage plate assembly 110 may be formed in a triple structure so as to increase the binding property with the foundation concrete layer due to its own weight when pouring the concrete mortar for forming the upper protective concrete layer. Will be explained.

Referring to FIG. 4, the drainage plate assembly 210 includes a main drainage plate member 120, a heat insulation drainage plate member 130, and an auxiliary drainage plate member 140.

The first through hole 125 is formed on the bottom surface of the first support pillar 122 of the main drain plate member 120.

In addition, a second through hole 135 is formed on a lower surface of the second support column 132 of the heat insulation drainage plate member 130.

The auxiliary drainage plate 140 may include the first and second support pillars 122 by the weight of the mortar of the upper protective concrete layer, in which the second support pillars 132 are slidably inserted and placed on top of the main drainage plate member 120. Auxiliary support pillars 142 descending along 132 to be able to contact the upper surface of the base concrete layer 10 are connected by a connecting strip 144 as a connecting portion.

The connecting strip 144 may be formed to be bent to have a buffer.

The auxiliary drain plate 140 is preferably formed of a flexible flexible synthetic resin material.

In addition, unlike the structure of the connecting strip shape shown in the connecting portion 141 of the auxiliary drain plate 140, the connecting portion as shown in Figure 5 the third base plate for connecting the upper portion of the auxiliary support pillar 142 in a plate shape Of course, it can be applied to the (141) shape.

Here, the lower surface of the auxiliary support pillar 142 has a closed structure, and may be formed in a structure having a through hole different from the illustrated example.

The groundwater drainage device 200 to which the triple plate drain plate assembly 210 is applied is shown in FIG. 6.

On the other hand, as shown in Figure 7 in order to further increase the heat insulating ability through the first and second through holes 125, 135 from the lower surface 143 of the auxiliary support pillar 142 closed the lower support (143) The first insulating layer 191 laminated with a heat insulating material may be further formed below the upper protective concrete layer 20 to the lower surface of the first support pillar 122.

In this case, the first insulation layer 191 may be formed by applying a heat insulating resin that may be solidified through a curing process, and then pouring the upper protective concrete layer into mortar.

In addition, as illustrated in FIG. 8, the second insulating layer 193 may be formed by being seated or bonded to the upper surface of the second plate 131 with a heat insulating material such as styrofoam.

In this case, the second insulation layer 193 may have a structure formed in a plate shape having a hole into which the first support pillar 122 may be inserted, and the thickness of the second insulation layer 193 may be a first base plate after construction. Spaced apart from 121 and applied so that the insulating air layer 150 can be maintained.

In the groundwater drainage system, when the basement formation area is wide, as shown in FIG. 9, the auxiliary catchment passage 155 leading from the catchment space between the auxiliary drainage plate 140 and the foundation concrete layer 10 to the sump 30 is provided. Of course, it can form more.

In addition, the upper protective concrete layer 20 from the upper surface 21 of the upper protective concrete layer 20 as shown in FIG. 10 so that outside air can flow from the upper protective concrete layer 20 to the insulating air layer 150. The outdoor air inlet 156 drawn downward to communicate with the insulating air layer 150 is formed.

Here, the outside air inlet 156 is a heat insulating air layer (1) on the first base plate 121 of the area formed in the outside air inlet 156 so that outside air on the upper protective concrete layer 20 can be introduced into the heat insulating air layer 150. The vent hole 128 that is in circulation with the 150 may be formed.

On the other hand, the vent pipe 170 is the third base plate 141 and the second base plate (141) of the auxiliary drain plate 140, as shown in Figure 11 and 12 for inflow and outflow of the outside air to the insulating air layer 150 131 is coupled to the insulated air layer 150 in communication with the branch pipe portion 173 is spaced apart from each other from the main duct 172 so as to be introduced and discharged to the adiabatic air layer 150 through the heat insulating air layer 150. By the insulating air layer 150 and the structure coupled to the middle can be applied.

Here, reference numeral 177 is a first coupling hole formed on the second base plate 131 and sealably coupled to the branch pipe part 173, and reference numeral 176 is formed on the third base plate 41 to make the branch pipe part. It is a second coupling hole coupled to be sealed while allowing the penetration of (173).

In this structure, the end of the main pipe part 172 of the ventilation pipe 170 may be installed to extend to a position where the outdoor air or the basement floor indoor air can be introduced and discharged.

In addition, when the hot air is to be supplied to the heat insulating air layer 150, the hot air supplier 180 may be connected to the main pipe 172 of the ventilation pipe 170.

120: main drain plate member 130: heat insulation drain plate member
140: auxiliary drain plate 150: insulating air layer
180: hot air supply

Claims (11)

In the groundwater drainage system to collect the infiltration water flowing between the foundation concrete layer of the building and the upper protective concrete layer placed on top of the foundation concrete layer to discharge to the sump well,
A main drain plate member disposed between the upper protective concrete layer and the foundation concrete layer, the main drain plate member including a first base plate and a plurality of first support pillars protruding downward from the first base plate;
The second support plate is installed below the main drain plate member and has a second base plate and a plurality of second support pillars protruded downward from the second base plate so that the first support pillars can be inserted therein. The second base plate is spaced downwardly with respect to the first base plate in the state that the first support pillar is inserted in the support to the heat insulating drainage plate to form a heat insulating space layer between the first base plate A groundwater drainage device comprising: a member. The groundwater drainage system of claim 1, wherein a lower surface of the first support pillar and a lower surface of the second support pillar are closed. The method of claim 1,
A first through hole is formed on a lower surface of the first support pillar, and a second through hole is formed on a lower surface of the second support pillar.
The second support pillars are slidably inserted and lowered along the first and second support pillars by the weight of the mortar of the upper protective concrete layer which is placed on the upper portion of the main drainage plate member to the upper surface of the foundation concrete layer. Groundwater drainage further comprises a; auxiliary drainage pillars in contact with the auxiliary drainage plate connected by the connecting portion. The drainage plate assembly according to claim 3, wherein the height of the second support pillar is higher than the height of the auxiliary support pillar, and the height of the first support pillar is higher than that of the second support pillar. The groundwater drainage device according to claim 4, wherein the heat insulation drainage plate member is formed so that adjacent other heat insulation drainage plate members and the edge portion overlap each other. 6. The second base plate of claim 5, wherein the second base plate has a main portion formed in a rectangular plate shape, and an upper portion of the second base plate along an edge on a first surface of the edge of the main portion and a second surface in an orthogonal direction adjacent to the first surface. The coupling bone is formed in the first portion is formed with a coupling bone inserted downward and the edge of the third surface and parallel to the first surface opposite to the first surface on the opposite side of the first surface Groundwater drainage, characterized in that it has a second portion formed with a coupling piece to enter into. The method according to claim 6, wherein the lower surface of the auxiliary support pillar is closed, the first insulating layer laminated with a heat insulating material under the upper protective concrete layer from the lower surface of the second support pillar to the lower surface of the first support pillar; Groundwater drainage, characterized in that further formed. The groundwater drainage device of claim 6, further comprising: a second insulation layer stacked on an upper surface of the second base plate with a heat insulating material spaced apart from the first base plate. According to claim 6, The upper protective concrete layer is formed in communication from the upper surface of the upper protective concrete layer to the insulating air layer is formed in the outside air inlet so that the outside air is introduced into the insulating air layer downwardly,
The groundwater drainage device, characterized in that the first base plate of the outside air inlet window forming region is formed with a vent hole that passes through the insulating air layer. The groundwater drainage device according to claim 6, further comprising: a warm air supply for supplying warm air through the thermal insulation air layer. The method of claim 10, wherein the connecting portion of the auxiliary drain plate is a third base plate for connecting the upper portion of the auxiliary support pillar in a plate shape,
And a ventilation pipe coupled to communicate with the insulating air layer through the third base plate and the second base plate, and connected to allow the warm air or the outside air to flow into and out of the insulating air layer.
The hot air supplier is a groundwater drainage, characterized in that for supplying warm air through the ventilation pipe.

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