KR102277457B1 - Underground wall structure with advanced vantilation and construction method of that - Google Patents

Abstract

The present invention relates to an underground structure, and more particularly, to an underground wall structure capable of effectively ventilating an underground space and a construction method. The underground wall structure and construction method according to the embodiment of the present invention allows the external air above the ground and the air below the ground to circulate through the space formed between the underground outer wall and the inner wall, thereby effectively ventilating the underground space to prevent condensation or moisture. has the effect of being able to remove it.

Description

Underground wall structure with improved ventilation and construction method {UNDERGROUND WALL STRUCTURE WITH ADVANCED VANTILATION AND CONSTRUCTION METHOD OF THAT}

The present invention relates to an underground structure, and more particularly, to an underground wall structure capable of effectively ventilating an underground space and a construction method.

As building technology develops, buildings such as office buildings and apartments are becoming taller, and urban development is accelerating. Accordingly, it is a time when the importance of underground facilities is being emphasized as necessary spaces other than housing, such as parking spaces, are insufficient. In general, because underground facilities are built under the surface of the ground, ventilation does not occur smoothly, and moisture from the groundwater flowing around the facility or dew condensation due to the temperature difference between the ground and the building is formed on the underground wall, causing subsidence or damage to the underground facilities. It causes corrosion, etc. In order to block the inflow of moisture or infiltration water due to condensation from the underground walls of these underground facilities, waterproofing can be applied to the underground walls, but the waterproofed basement walls often corrode the waterproofing layer under the influence of the load caused by the earth pressure. As a result, groundwater or moisture infiltrates into the underground wall frequently.

1 is a view showing a conventional underground wall structure disclosed in Korean Patent Laid-Open Publication No. 10-1996-0004682 (Inner wall structure for preventing condensation of an underground wall). The conventional underground wall structure consists of an outer wall against earth pressure, a floor slab integrally poured on the upper and lower portions of the outer wall, and an inner wall constructed to form a predetermined space inside the outer wall, but the inner wall Ventilation holes are formed at predetermined positions so that the air inside the basement and the air in the space can mutually circulate. However, since the air inside the basement is only a small volume sealed under the ground as described above, the flow of air circulating between the space between the basement walls and the basement space is inevitably weak. Therefore, there is a problem in that it is difficult to effectively remove dew or moisture formed on the wall of the underground space in such an air circulation structure.

In addition, a construction method in which a cement block is double laminated on the inside of an underground wall and a hole for air circulation is formed in various shapes between the space between the walls and the interior space of the basement has been disclosed.

FIG. 2 is a view showing a conventional underground wall structure disclosed in Korean Patent Publication No. 10-0592423 (a ventilation block forming a wall of a building and a construction method thereof). In the conventional underground wall structure, an inner wall composed of a plurality of blocks is disposed with a space spaced apart from the outer wall. At this time, a through hole is formed in the middle of the block body, but the other side of the through hole constitutes a vent hole in which the hole is enlarged in the shape of a fallopian tube, and the central upper surface of the vent hole is configured with a thicker load reinforcement part. However, in the case of such a construction method, a difference between humidity and temperature may occur due to the characteristics of the cement, so that dew condensation may occur on the surface, and the growth of mold or bacteria due to moisture may be easily achieved. In addition, regardless of the material of the inner wall, since the distribution path is still configured for air sealed inside the underground space, effective ventilation is not achieved.

Laid-open Patent Publication No. 10-1996-0004682 (1996.02.03) Registered Patent Publication No. 10-0592423 (2006.06.22)

The present invention is to solve the above problems, by allowing the air outside the ground and the air to circulate through the space formed between the outer wall and the inner wall of the basement, thereby enabling effective ventilation of the underground wall structure and The purpose is to provide a construction method.

In order to solve the above problems, the underground wall structure of the present invention is a building structure between the underground outer wall surrounding the underground space and the underground outer wall by being located in the underground space at a predetermined distance from the underground outer wall. a decompression space is formed in the inner wall of the basement in which a ventilation passage through which the air of the underground space can be introduced into the decompression space is provided in a portion of the wall surface, and the air introduced into the decompression space by being coupled to the upper groove of the decompression space a ground exhaust device for discharging to the ground, wherein the ground exhaust device constitutes a path through which the air of the decompression space flows, one side is coupled to the upper groove of the decompression space, and the other side is exposed to the atmosphere on the ground. It may include an exhaust pipe and a rotatable exhaust fan located at one side of the internal space of the exhaust pipe to induce an air flow so that the air inside the exhaust pipe is discharged to the ground.

The underground outer wall may be made of cement and aggregate.

The decompression space may be formed with a distance of several cm to several tens of cm between the underground outer wall and the underground inner wall.

The decompression space may be divided into a plurality of spaces by the underground inner wall.

When the decompression space is divided into a plurality of spaces, the ground exhaust device may be separately formed for each of the divided spaces.

When the decompression space is divided into a plurality of spaces, a connection pipe connecting the plurality of divided spaces may be further formed.

The underground inner wall may be made of at least one of cement, aggregate, metal, and synthetic resin.

The ventilation passage may be formed at a lower end of the underground inner wall.

The underground inner wall may have a structure in which a plurality of inner wall blocks are stacked in close contact with each other left and right or up and down.

The underground inner wall may be formed by including at least one inner wall block provided with a ventilation passage.

The inner wall block provided with the ventilation passage may be located at the lower end of the underground inner wall.

The ventilation passage may be formed in a slot structure.

The exhaust pipe may have a circular or rectangular shape.

The exhaust pipe may be made of a metal or synthetic resin material.

The exhaust pipe may be bent in a U-shape so that the other side exposed to the ground atmosphere may be formed toward the ground surface.

The underground wall structure may further include an air supply fan for introducing atmospheric air into the underground space.

By introducing air in the atmosphere into the underground space through the air supply fan, the air pressure in the decompression space may be lower than the air pressure in the underground space and higher than the air pressure in the atmosphere.

In addition, the above-ground exhaust device for underground air ventilation of the present invention forms a decompression space by locating a predetermined distance between the underground outer wall surrounding the underground space and the underground outer wall, and the air in the underground space flows into the decompression space. In a building structure including an underground inner wall provided with a ventilation passage in a partial area of the wall surface to flow in, it constitutes a path through which the air of the decompression space flows, one side is coupled to the upper groove of the decompression space, and the other side is on the ground. It may include an exhaust pipe exposed to the atmosphere, and a rotatable exhaust fan positioned at one side of the internal space of the exhaust pipe to induce an air flow so that the air inside the exhaust pipe is discharged to the ground.

In addition, the method for constructing an underground wall structure of the present invention comprises the steps of: forming an underground outer wall for protecting the underground space in a state in which the underground space is formed; The steps of providing a decompression space between the underground outer wall and the underground inner wall by forming an underground inner wall in the central direction of the, forming a connection groove of a certain size in an upper portion of the reduced pressure space; and forming a ground exhaust device for discharging the air in the underground space to the ground by being coupled and the other side being exposed to the ground atmosphere, wherein the ground exhaust device constitutes a path through which the air of the decompression space flows, , an exhaust pipe, one side of which is coupled to a groove in the upper or side of the decompression space, and the other side is exposed to the atmosphere on the ground, and is located on one side of the internal space of the exhaust pipe, so that the air inside the exhaust pipe is discharged to the ground. It may include a rotatable exhaust fan for inducing.

The underground wall structure and construction method according to the embodiment of the present invention allows the external air above the ground and the air below the ground to circulate through the space formed between the underground outer wall and the inner wall, thereby effectively ventilating the underground space to prevent condensation or moisture. has the effect of being able to remove it.

1 is a view showing a conventional underground wall structure,
2 is a view showing another conventional underground wall structure;
3a to 3d are cross-sectional views of an underground wall structure with improved ventilation according to an embodiment of the present invention;
4 is a cross-sectional view showing another embodiment of a ground exhaust device in the underground wall structure with improved ventilation according to an embodiment of the present invention;
5 is a perspective view showing another embodiment of an underground inner wall in an underground wall structure with improved ventilation according to an embodiment of the present invention;
6 is a perspective view of an underground wall structure with improved ventilation according to an embodiment of the present invention;
7A and 7B are plan views when the decompression space is divided into a plurality in the basement wall structure with improved ventilation according to an embodiment of the present invention.

The terminology used herein is for the purpose of referring to specific embodiments only, and is not intended to limit the invention. As used herein, the singular forms also include the plural forms unless the phrases clearly indicate the opposite. The meaning of "comprising," as used herein, specifies a particular nature, region, integer, step, action, element, and/or component, and includes any other particular nature, region, integer, step, operation, element, component, and It does not preclude the presence or addition of/or groups.

Although not defined otherwise, all terms including technical and scientific terms used herein have the same meaning as commonly understood by those of ordinary skill in the art to which the present invention belongs. Commonly used terms defined in the dictionary are additionally interpreted as having a meaning consistent with the related technical literature and the presently disclosed content, and unless defined, they are not interpreted in an ideal or very formal meaning.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3A to 3D are cross-sectional views of an underground wall structure with improved ventilation according to an embodiment of the present invention. First, referring to FIG. 3a, the underground wall structure 100 with improved ventilation of the present invention is installed at a predetermined distance from the underground outer wall 110 installed to protect the underground space 102 from underground soil. A ground exhaust device 130 capable of discharging air in the underground space 102 to the ground by forming a reduced pressure space 150 between the underground inner wall 120 and the underground outer wall 110 and the underground inner wall 120 . may include

The underground space 102 may be a space such as an underground house for a residence, an underground office for business, an underground parking lot in which a vehicle can be parked, or the like. In general, in the underground space 102 , a path connected to the ground may be formed by a connection passage 140 such as a door through which a user can enter and exit the underground space 102 or a glass window disposed on the ground. However, since the door remains closed while the user does not enter, and the glass window is often closed due to the influence of rain, snow, or wind from the outside, only this connection passage 140 is the interior of the underground space 102 It is difficult to ventilate the air or remove moisture or condensation. In particular, the underground space 102 has a structure in which it is difficult to maintain a comfortable environment by ventilating the air because it is difficult for the ground air to flow as the depth descends from the ground.

The underground outer wall 110 surrounding the underground space 102 is formed to protect a user located in the underground space 102 from infiltration of soil or groundwater existing underground, moisture or condensation generated therefrom, and the like. In general, the underground outer wall 110 will be formed using cement and aggregate. Here, although the case in which the underground outer wall 110 is formed in a form surrounding the outside of the underground space 102 is illustrated, the floor of the underground space 102 is hard and flat using the same material as the underground outer wall 110 . , it may be possible to form the ground integrally with the underground outer wall (110).

The underground wall structure 100 with improved ventilation of the present invention installs the underground inner wall 120 between the underground space 102 and the underground outer wall 110, and is formed between the underground outer wall 110 and the underground inner wall 120 By lowering the pressure of the space to be formed than the pressure of the underground space 102 , the air in the underground space 102 can be discharged to the ground through the decompression space 150 . To this end, the underground inner wall 120 is formed to be spaced apart from the underground outer wall 110 by a certain distance in the underground space 102 direction. For this reason, even when water leakage or condensation occurs in the underground outer wall 110 , it is possible to block the influence of water leakage or condensation on the underground space 102 by the underground inner wall 120 .

The underground inner wall 120 may be made of cement and aggregate, or may be made of metal or reinforced resin in the same manner as the underground outer wall 110 . The underground inner wall 120 may be separately installed on the ground of the underground space 102, and may be constructed integrally with the ground by using the same material in the process of forming the underground space 102 and the underground outer wall 11. will be. The underground inner wall 120 has at least one ventilation passage 125 on one side in order to introduce the air of the underground space 102 into the decompression space 150 . The ventilation passage 125 may be formed in the upper or lower portion of the underground inner wall 120 , and is formed in the lower portion so that the air introduced through the connection passage 140 is circulated in the underground space 102 and then discharged. It is preferable to be At this time, the ventilation passage 125 is several tens of cm, for example, so as not to obstruct the air flow of the underground space 102 by the drainage facility formed in the underground space 102 or the decompression space 150 or water introduced from the outside. For example, it would be desirable to form at a height of 30 cm or more.

In the decompression space 150 formed between the underground outer wall 110 and the underground inner wall 120 , the air introduced from the underground space 102 through the ventilation passage 125 is discharged to the ground through the ground exhaust device 130 . make it possible The width of the decompression space 150, that is, the distance between the underground outer wall 110 and the underground inner wall 120 may vary depending on the area of the underground space 102 and the exhaust performance of the above-ground exhaust device 130, from several cm to several tens of centimeters. It can be changed in various ways up to cm. This decompression space 150 not only serves as a passage for discharging the air of the underground space 102 to the ground, but also reduces the pressure exerted by the underground soil on the underground outer wall 110 to reduce the effect on the underground space 102 . It may also have a dampening effect. Therefore, it is preferable to determine the width and area of the decompression space 150 in consideration of both the decompression effect of the earth pressure and the discharge effect of the air.

The decompression space 150 is formed in a vertical direction between the underground outer wall 110 and the underground inner wall 120 , and a ground exhaust device 130 for discharging air to the ground may be formed in the upper portion of the decompression space 150 . have. The ground exhaust device 130 may include an exhaust pipe 134 for forming an exhaust passage of air connected to the upper portion of the decompression space 150 and an exhaust fan 132 provided at an outlet portion of the exhaust pipe 134 . have. The exhaust pipe 134 is formed in a circular or rectangular shape and leads from the upper portion of the decompression space 150 to the ground atmosphere, and may be made of a metal material such as copper, zinc, chromium, or a synthetic resin material such as polyethylene. The exhaust fan 132 receives power from a power supply device provided inside or outside and serves to supply rotational force so that air flows from the underground direction of the exhaust pipe 134 to the ground direction. At this time, the size and rotation speed of the exhaust fan 132 may be adjusted according to the area of the decompression space 150 or the air discharge performance of the underground space 102 . On the other hand, although only one ground exhaust device 130 may be formed in a building having the underground space 102 , a plurality of ground exhaust devices 130 may be formed at different locations for efficient air circulation.

Meanwhile, the ground exhaust device 130 may be connected through the upper ceiling of the decompression space 150 , but it may be difficult to form in a vertical direction due to the structure of the ground building. In this case, it may lead to the ground through a connection passage formed in the underground outer wall 110 or the underground inner wall 120 at a predetermined height of the decompression space 150 . 3B and 3C are cross-sectional views illustrating a case in which the ground exhaust device 130 is connected to the ground through the connection passage of the underground outer wall 110 or the underground inner wall 120 .

First, referring to FIG. 3B , the ground exhaust device 130 leads to the outside of the underground outer wall 110 through a connection passage formed in the upper portion of the underground outer wall 110 . Therefore, when the exhaust fan 132 of the ground exhaust device 130 operates, the air in the underground space 102 flows into the decompression space 150 , and after moving to the upper part of the decompression space 150 , it is again underground. It flows into the ground exhaust device 130 connected to the outside of the underground outer wall 110 through the upper connection passage of the outer wall 110 . As such, when the ground exhaust device 130 is extended through the outer surface of the underground outer wall 110, it may be mainly used when there is no other building adjacent to the outside of the building.

In addition, referring to FIG. 3C , the ground exhaust device 130 may lead through a connection passage formed on the upper portion of the underground inner wall 120 , and may lead to the ground through a path formed in the ceiling portion of the underground space 102 . Such a structure may be used when there is an adjacent building and it is difficult to connect the ground exhaust device 130 through the underground outer wall 110 due to the adjacent building.

3D shows a case in which the air supply fan 142 is provided in the connection passage 140 so that atmospheric air can be introduced into the underground space 102 . Referring to FIG. 3D , the air supply fan 142 provided in the connection passage 140 may forcibly introduce fresh air into the underground space 102 . In this case, if the air pressure of the atmosphere is P0, the air pressure of the underground space 102 may be P2 higher than P0. The air pressure P2 of the underground space 102 may be changed according to the inflow performance of the air supply fan 142 . The air introduced into the underground space 102 through the air supply fan 142 is moved to the decompression space 150 through the ventilation passage 125, and will be discharged back to the atmosphere through the exhaust fan 132 (Return Air). At this time, since the air in the decompression space 150 is discharged into the atmosphere by the exhaust fan 132 , the air pressure P1 in the decompression space 150 is lower than the air pressure P2 in the underground space 102 . Therefore, comparing the pressures of the air pressure P0 in the atmosphere, the air pressure P2 in the underground space, and the air pressure P1 in the decompression space 150, the P2 air pressure is the highest, then the P1 air pressure is the highest, and the P0 air pressure will be the lowest.

In this way, when the air pressure of the underground space 102 is increased through the air supply fan 142 and discharged back to the atmosphere through the decompression space 150 , the odor or polluted air is introduced into the underground space 102 . more effective in cases For example, when the drain hole 172 is installed at the bottom of the underground space 102 , contaminated air may be introduced into the underground space 102 from leachate or contaminated water existing in the drain pipe 174 , thereby generating a bad odor. In this case, when the air in the atmosphere is introduced into the underground space 102 through the air supply fan 142, the air pressure P2 of the underground space 102 increases, so that the contaminated air from the drain pipe 174 through the drain hole 172 is It becomes difficult for air to flow in, and the air in the underground space 102 can be maintained in a clean state.

4 is a cross-sectional view showing another embodiment of the above-ground exhaust device in the underground wall structure with improved ventilation according to the embodiment of the present invention. Referring to FIG. 4 , the exhaust pipe 134 of the ground exhaust device 130 is formed of a circular or rectangular pipe, and one pipe is formed between the underground outer wall 110 and the underground inner wall 120 , and the upper part of the decompression space 150 is formed. connected to, and the other pipe is exposed to the ground air, thereby forming a movement path through which the air in the decompression space 150 can be discharged to the ground.

At this time, a rotatable exhaust fan 132 is provided inside the pipe exposed to the ground air to form a flow in which the air in the decompression space 150 moves to the ground. The exhaust fan 134 is formed in the form of a propeller rotatable using an internal power source or an external power source. Because it is exposed to the air on the ground, when rain, snow, dust, etc. enter, electrical or mechanical damage such as short circuit or short circuit defects may occur. Therefore, it is preferable that the pipe exposed to the air on the ground is made to face the side or the lower direction rather than the upper direction. 4 shows a case in which the exhaust pipe 134 is bent in a U-shape and is constructed to face the lower surface of the ground, that is, the ground direction.

Alternatively, the structure may be twisted once or twice to prevent rain or snow from entering the inside. When the exhaust pipe 134 is formed with such a twisted structure, it may be configured in the form of a corrugated pipe having elasticity.

5 is a perspective view showing another embodiment of an underground inner wall in the underground wall structure with improved ventilation according to an embodiment of the present invention. Referring to FIG. 5 , the underground inner wall 120 may be formed in a structure in which a plurality of inner wall blocks 120a, 120b, and 120c are stacked. The plurality of inner wall blocks 120a, 120b, and 120c may be formed using cement and aggregate, or may be made of a material of a lightweight metal or synthetic resin. The inner wall blocks 120a, 120b, and 120c may have a rectangular parallelepiped shape, but may be coupled to each other in various shapes such as a triangle or a hexagon.

The underground inner wall 120 forms the entire structure by stacking the left and right side surfaces or the upper and lower sides of the plurality of inner wall blocks 120a, 120b, and 120c to be in close contact with each other and stacked. The cross-sections adjacent between the inner wall blocks 120a, 120b, and 120c may be coupled to form a 'C' shape of the interlocking structure, and the interlocking protrusion and the interlocking groove may be formed as a pair and may be coupled to each other in a fitting structure. Alternatively, it may be coupled to the adjacent surface by a fastening means such as a wooden peg or screw.

Ventilation passages 125b and 125c are provided in some of the inner wall blocks among the plurality of inner wall blocks 120a, 120b, and 120c so that air of the underground space 102 can be introduced into the decompression space 150 . The ventilation passage may be formed to have a predetermined area such as a rectangle or a circle in the central portion of the inner block (120b, 125b), or may be formed in the form of a slot having a constant height along the horizontal plane of the inner block (120c, 125c) ). The internal blocks 120b and 120c provided with the ventilation passages 125b and 125c are arranged in one or a plurality of partial areas among the parts constituting the underground inner wall 120 so that the air of the underground space 102 is discharged. will be able The internal blocks 120b and 120c provided with the ventilation passages 125b and 125c are preferably disposed at the lower end of the underground inner wall 120 for smooth air flow in the underground space 102 . However, it will be preferable to form at a certain height, for example, 30 cm or more so that the ventilation function is not limited by the water flowing into the drain or the underground space 102 . The contractor of the underground space 102 builds the underground inner wall 120 by stacking the inner blocks 120b and 120c with the ventilation passage 125 and the inner block 120a without the ventilation passage in various combinations. It may be configured in various forms.

6 is a perspective view of an underground wall structure with improved ventilation according to an embodiment of the present invention. Referring to FIG. 6 , in a state in which the underground space 102 is formed, an underground outer wall 110 for protecting the underground space 102 from soil or groundwater is formed. Next, the underground inner wall 120 formed by stacking a plurality of inner wall blocks 120a, 120b, and 120c in the central direction of the underground space 102 at a predetermined distance from the underground outer wall 110 is formed. The decompression space 150 is formed by the distance existing between the underground outer wall 110 and the underground inner wall 120 . A groove 160 of a certain size is formed in the upper ceiling of the decompression space 150 , and a ground exhaust device 130 for discharging air in the underground space 102 to the ground is coupled thereto.

In the underground space 102, air may be introduced through a connection passage 140 such as an entrance door or a glass window disposed on the ground, and among the plurality of inner wall blocks 120a, 120b, and 120c constituting the underground inner wall 120, Air flows into the decompression space 150 through the inner wall blocks 120b and 120c in which the ventilation passages 125b and 125c are formed.

The air introduced into the decompression space 150 through the ventilation passages 125b and 125c is discharged to the ground through the ground exhaust device 130 connected to the groove 160 of the ceiling wall of the decompression space 150 . In the ground exhaust device 130, a flow of air moving from the underground to the ground is formed due to the rotation of the exhaust fan 134 in the portion exposed to the ground. As for the exhaust pipe 134 of the ground exhaust device 130, it is effective that the direction of the pipe exposed on the ground faces the ground so that rain or snow does not flow therein.

On the other hand, in the underground wall structure of the present invention, the structure of the underground outer wall 110 and the underground inner wall 120 may be formed in various ways. In order to form the decompression space 150, the underground inner wall 120 is formed to be spaced apart from the underground outer wall 110 at a certain distance, but due to factors such as the structure or safety of the building, the underground outer wall 110 and the underground inner wall ( The decompression space 150 between 120 may be divided into a plurality of spaces. In this case, the ground exhaust device 130 may be formed for each of the divided decompression spaces 150 , or one ground exhaust device 130 may be formed by creating a connection passage connecting the divided decompression spaces 150 . There will be.

7A and 7B are plan views showing a case in which the decompression space is divided into a plurality in the basement wall structure with improved ventilation according to an embodiment of the present invention. First, referring to FIG. 7A , the decompression space 150 may be divided into a plurality of decompression spaces 150a and 150b by the structure of the underground inner wall 120 . At this time, since air is introduced from the subterranean space 102 into the divided decompression spaces 150a and 150b, respectively, ground exhaust for discharging air to the ground for each of the divided decompression spaces 150a and 150b for effective air discharge. Devices 130a and 130b may be formed individually. At this time, as described above, the ground exhaust devices 130a and 130b may be connected to the ground through the ceiling of the decompression space 150 , or connect the connection passage of the underground outer wall 110 or the connection passage of the underground inner wall 120 . It may be connected to the ground through

On the other hand, if a connection pipe 180 connecting the divided decompression spaces 150a and 150b is additionally formed even if a plurality of divided decompression spaces 150a and 150b exist as shown in FIG. 7b, a plurality of decompression spaces 150a, 150b), by installing the ground exhaust device 130a on only one side, the air may be discharged to the ground. In this way, if a plurality of divided decompression spaces 150a and 150b are formed, the effect may be high when there is a space in which air is relatively easily contaminated, such as a toilet 102a, in the underground space 102 . For example, if there is a toilet 102a in the basement space 102, a divided decompression space 150b is formed on one wall of the toilet 102a, and air in the toilet 102a is transferred through the divided decompression space 150b. By discharging, it is possible to prevent the air in the underground space 102a from being polluted.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, those of ordinary skill in the art to which the present invention pertains may be embodied in other specific forms without changing the technical spirit or essential features of the present invention. can be understood as Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the following claims rather than the above detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be interpreted as being included in the scope of the present invention. do.

100: underground wall structure 102, 102a: underground space
110: basement outer wall 120: underground inner wall
120a, 120b, 120c: inner wall block
125, 125b, 125c: ventilation passages
130, 130a, 130b: ground exhaust
132: exhaust fan
134: exhaust pipe 140: connecting passage
142: fan for supply air 150, 150a, 150b: reduced pressure space
160: groove in the ceiling wall 172: drain hole
174: drain pipe 180: connector pipe

Claims (19)

In the underground wall structure,
an underground outer wall that encloses the underground space;
By being positioned in the underground space at a predetermined distance from the underground outer wall, a decompression space is formed between the underground outer wall in a vertical direction from the ground, and a ventilation passage through which air from the underground space can be introduced into the decompression space is formed on the wall surface. an underground inner wall provided at the lower end of the;
a ground exhaust device coupled to the upper groove of the decompression space to discharge air introduced into the decompression space to the ground; and
A fan for supplying air, which is located in the connection passage with the ground in the upper part of the underground space and introduces ground air into the underground space below the connection passage;
The ground exhaust system is
One side is coupled to the upper groove of the decompression space and the other side is exposed to the ground atmosphere and leads to the ground atmosphere from the upper part of the decompression space. an exhaust pipe rising toward the upper groove of the space and forming a path discharged to the ground, the other side of which is formed to face the ground; and
Located on one side of the internal space of the exhaust pipe, in order to form a flow in which the air in the decompression space rises from the bottom and moves to the ground, a rotational force is supplied so that the air flows from the underground direction of the exhaust pipe to the ground direction. including; a fan;
The air supply fan introduces ground air into the underground space to increase the air pressure in the underground space, and the air in the reduced pressure space is discharged by the exhaust fan, and the air pressure in the reduced pressure space is the air pressure in the underground space. lower and higher than the air pressure in the ground atmosphere,
The decompression space is divided into a plurality of spaces by the underground inner wall, and a connection pipe connecting the divided spaces is further formed.
delete The method of claim 1,
An underground wall structure in which the above-ground exhaust device is separately formed for each of the plurality of divided spaces.
delete The method of claim 1,
The basement wall is
A plurality of inner wall blocks are stacked in close contact with each other left and right or up and down,
An underground wall structure in which at least one inner wall block provided with a ventilation passage is included in the lower end of the underground inner wall. delete delete delete delete delete delete delete delete delete delete delete delete delete delete

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