KR20100084085A - Basement for preventing submersion - Google Patents

Abstract

PURPOSE: It supplies the compressed air inside cellar and the basement structure for the flooding prevention discharges the water flowing in into the cellar inside to the cellar outside. The flooding of the switch board is prevented. CONSTITUTION: A cellar(100) comprises the drain of the penetration hole shape in the flooding water level lower. It supplies the compressed air inside cellar and the compressed air supply means(200) discharges the water flowing in into the cellar inside to the drainage district. The water level detecting measure(300) senses the water level of the water flowing in into the cellar inside. In the sidewall of cellar, the ventilation opening(120) locates. The gallery(500) for the ventilation comprises the inside box winnower communicated with the outside box winnower and ventilation opening.

Description

Basement for preventing submersion

The present invention relates to an inundation prevention underground structure configured to prevent the distributor from being flooded when water is introduced into a cellar having a distributor installed therein, and more specifically, a high pressure into the cellar when water is introduced into the cellar. It relates to an underground structure for immersion prevention to be configured to prevent the ingress of the distributor by blowing the compressed air of the basement to push the water in the basement to the outside of the basement.

Recently, underground construction projects have been underway to bury transformers, related distributors, and wires installed in the air in the ground in consideration of the city's beauty and safety. At this time, when the distributor is mounted in the basement of the building, the basement is configured in a sealed structure so that water does not flow into the interior from the outside.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the conventional submerged underground structure.

1 is a cross-sectional view showing a conventional underground structure for preventing flooding.

As shown in FIG. 1, the conventional submersion prevention underground structure is equipped with an electric and mechanical facility 10 therein, a basement 20 embedded in the basement, and one end of the basement 20 is introduced into the basement 20. And a wire (30) connected to the mechanical facility (10), a wire and a pipe entrance (40) from which the wire (30) is drawn out of the basement (20), and a basement by inflowing outside air into the basement (20). 20) is configured to include a ventilation gallery (50) for ventilating the interior.

Ventilation opening 22 is formed on the side wall of the basement 20, and the ventilation gallery 50 has an outer ventilation opening 52 communicating with the outside and an inner ventilation opening 54 communicating with the ventilation opening 22. . Therefore, the outside air introduced into the outer vent holes 52 passes through the inside of the ventilation gallery 50 and passes through the inner vent holes 54 into the basement 20, and the muddy air in the basement 20 is vented. By exiting to the outside through the inner vent holes 54 and the outer vent holes 52, the inside of the basement 20 is ventilated.

In addition, the basement 20 is provided with a door 24 on one side which is opened during maintenance and repair of the electrical and mechanical equipment 10, the base 26 on which the electrical and mechanical equipment 10 is seated on the upper surface. Is provided on the bottom surface.

The door 24 is mounted in a sealed structure in the basement 20, the ventilation gallery 50 is formed in close contact with the basement 10 to cover the ventilation openings 22 formed in the basement 10, the basement Existing water is prevented from entering the basement 10. Therefore, even if the electrical and mechanical equipment 10 is buried underground, the risk of flooding is prevented.

However, the conventional submersion prevention underground structure configured as described above, when the rain or flooding, water is introduced through the outer vent opening 52 formed in the ventilation gallery 50, the inner vent opening 54 and the ventilation opening 22 By being accumulated inside the basement 20 through, there is a risk that the electrical and mechanical equipment 10 may be flooded.

At this time, since the basement 20 has a closed structure except for a portion in which the ventilation hole 22 is formed, the water once introduced into the basement 20 does not escape to the outside of the basement 20, and thus the basement (20) There is a problem that the more and more water is filled inside.

In addition, the conventional underground embedding distributor immersion prevention structure, the ventilation port 22 is in communication with the ventilation gallery 50 is located on the upper side wall of the basement 20 bar, which is introduced into the interior of the ventilation gallery 50 Water splashes on the bottom surface of the ventilation gallery 50 and is delivered to the inside of the basement 20 through the ventilation opening 22, whereby the electrical and mechanical equipment 10 mounted on the bottom surface of the basement 20 enters the water. The disadvantage is that it gets wet.

The present invention has been proposed to solve the above problems, and when the water is introduced into the basement in which the distributor is installed, it is possible to prevent the flooding of the distributor by discharging the introduced water to the outside of the basement, ventilation It is an object of the present invention to provide an underground structure for preventing flooding, which is configured not to splash into the distributor even though water is introduced through the gallery.

Inundation prevention underground structure according to the present invention for achieving the above object,

A basement in which a drain hole having a through hole shape is formed at a lower side thereof; And

Compressed air supply means for supplying compressed air into the basement to discharge the water introduced into the basement into the drain hole;

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It further comprises a water level detecting means for detecting the level of water introduced into the basement,

The compressed air supply means is operated to supply compressed air into the basement when the level of water introduced into the basement rises above the set height.

The basement is ventilated on the side wall,

It further comprises a ventilation gallery having an outer vent opening communicating with the outside, the inner vent communicating with the ventilation opening,

The ventilation opening and the inner ventilation opening are formed at a position that is submerged in the water flowing into the basement when the water level of the water flowing into the basement rises above a predetermined height.

It is coupled to surround the wire connected to the distributor, and further comprises a wire and a pipe entrance through which one end is introduced into the basement through the basement,

One end of the wire and the pipe entrance is located at a position that is submerged in the water introduced into the basement when the water level of the water introduced into the basement rises above the set height.

The wire and the pipe entrance and exit has a through hole formed in the upper side of the position higher than the drain for supply of the wire to the adjacent facility.

The drainage port is formed at a position to be submerged in the water introduced into the basement when the water level of the water introduced into the basement rises above a predetermined height.

The basement has a base that is formed so that the upper surface is not submerged in the water introduced into the basement when the water level of the water introduced into the basement is raised to a set height,

The distributor is installed on the upper surface of the base.

The submerged underground structure according to the present invention can prevent the flooding of the distributor by discharging the introduced water to the outside of the basement when water is introduced into the basement where the distributor is installed therein, the basement through the ventilation gallery Since water does not splash into the distributor even if water is introduced therein, there is an advantage in that breaker and damage of the distributor can be prevented.

Hereinafter, with reference to the accompanying drawings will be described in detail an embodiment of the submerged underground structure according to the present invention.

Figure 2 is a perspective view of the submerged underground structure according to the present invention, Figure 3 is a cross-sectional view showing the internal configuration when the submerged underground structure according to the present invention is buried underground.

As shown in Figures 2 and 3 underground construction for underground electrical and mechanical equipment 10 inundation prevention according to the present invention, the drain hole 110 of the through-hole shape is formed on the lower side and the door 140 on one side wall Is formed and the electrical and mechanical equipment (10) is installed inside the basement 100 is embedded in the basement, and the compressed water supplied into the basement (100) to the water introduced into the basement (100) the drain hole Compressed air supply means for discharging to 110 is configured to include.

As described above, when the drainage hole 110 having a through-hole shape is formed in the basement 100, water may flow into the basement 100 through the drainage hole 110, but the electrical and mechanical equipment 10 is flooded. When the water is filled in the basement 100 as much as possible, the compressed air supply means 200 is operated to supply the compressed air into the basement 100. As such, when compressed air is supplied into the cellar 100, the water in the cellar 100 is pushed out of the cellar 100 through the drainage port 110 by the pressure of the compressed air. Will not be flooded.

At this time, the compressed air supply means 200 can be operated only when water is introduced into the basement 100 so that there is a risk that the electrical and mechanical equipment 10 is flooded, the electricity for underground laying according to the present invention And the underground structure for immersion prevention of the mechanical equipment 10 is configured to further include a water level detecting means 300 for detecting the level of water introduced into the basement (100).

The water level detecting unit 300 detects the water level flowing into the basement 100 when the water level rises by a predetermined height, that is, the height of the inundation of the electrical and mechanical equipment 10, and supplies compressed air. Sending the operation signal to the means 200, the compressed air supply means 200 receives the operation signal from the water level detection means 300 by supplying compressed air into the basement 100, basement water in the basement 100 (100) to the outside.

When the water level detecting means 300 is provided as described above, the compressed air supply means 200 may be automatically operated only when water is introduced into the basement 100 so that the flooding of the electrical and mechanical equipment 10 is concerned. Since it is possible to prevent the waste of power due to unnecessary operation, there is an advantage that it is possible to more reliably prevent the immersion of the electrical and mechanical equipment (10).

At this time, the water level (that is, the set height) at which the operation signal generation of the water level detecting means 300 starts, may be variously set by the user according to the characteristics of the electrical and mechanical equipment 10 and various conditions. For example, if there is a risk of damage when the electrical and mechanical equipment 10 is in contact with water at least, the set height is set low, and even if the lower part of the electrical and mechanical equipment 10 is submerged, the electrical and mechanical equipment ( If there is no fear of damage, the set height may be set higher.

In addition, a side wall of the basement 100 is provided with a ventilation gallery 500 for ventilation inside the basement 100. A ventilation opening 120 is formed at the side wall of the basement 100, and the ventilation gallery ( In the 500, an outer vent 510 communicating with the outside and an inner vent 520 communicating with the vent 120 are formed. The principle and structure in which the interior of the basement 100 is ventilated through the ventilation gallery 500 are equally applicable to the conventional underground laying electric and mechanical facilities 10, and a detailed description thereof will be omitted.

At this time, when the ventilation hole 120 and the inner ventilation hole 520 is formed at a position higher than the water level when the fear of immersion of the electrical and mechanical equipment 10 occurs (that is, the compressed air supply means 200 is operated) When formed at a position higher than the water level at the start time), the compressed air supplied into the basement 100 by the compressed air supply means 200 to the ground through the ventilation port 120 and the inner vent 520 Since it is discharged, the water inside the basement 100 is not pushed out of the basement 100 through the drain 110.

Therefore, the ventilation port 120 and the inner vent 520 is the basement 100 so that the compressed air supplied by the compressed air supply means 200 does not leak through the vent hole 120 and the inner vent 520. When the water level of the water flowing into the inside is raised above the set height is preferably formed in a position to be submerged in the water flowing into the basement (100).

In addition, the wires and pipes 400 connected to the electric and mechanical equipment 10 embedded in the basement are wrapped by the wires and the pipe entrances 410 so that no gap is generated in the portion that penetrates the basement 100. When the lower end of the wire and the pipe entrance 410 is located at a position higher than the water level at the time when the compressed air supplying means 200 starts to operate, the compressed air is moved into the basement 100. There is a fear of leaking to the outside through the pipe 400 and the electric wire and the pipe entrance 410. As such, when compressed air leaks out through the wires and pipes 400 and between the wires and the pipe entrances 410, the basement ( 100 inside the water is not pushed out of the basement 100 through the drain 110.

Therefore, one end of the wire and the pipe entrance 410 is preferably located in a position that is submerged in the water introduced into the basement 100 when the water level of the water introduced into the basement 100 rises above the set height. Do.

The basement 100 may be arranged in a separate space such as a distribution room, a machine room, and the like as needed to be adjacent to each other. A mobile passage, such as a staircase or a corridor, is provided between the separate spaces. At this time, since the electric power is normally connected to each other between the independent spaces, the electric wire and the pipe entrance 410 may have a communication hole 412 for supplying the electric wire to the adjacent facility on the upper side. The communication hole 412 is formed in the upper portion of the wire and the pipe entrance 410 in a position higher than the drain port 110.

The wire and pipe entrance 410 is connected to the inside of the basement through the lower end, similar to the ventilation gallery 500, and when the lower end is submerged in water at the time of flooding, the interior of the basement as in a single facility The compressed air filled in the state becomes unable to escape to the outside.

In addition, when the water level of the water introduced into the basement 100 is raised above the set height, if the drain hole 110 is not completely submerged in the water introduced into the basement 100, the part remains open, Since the compressed air supplied into the basement 100 leaks out of the basement 100 as it is through the open portion of the drain 110, the effect of discharging the water introduced into the basement 100 is significantly reduced. Therefore, the drain 110 is preferably formed in a position that is completely submerged in the water introduced into the basement 100 when the water level of the water introduced into the basement 100 is raised above the set height.

Underground structure for underground and underground electrical and mechanical equipment 10 submersion prevention according to the present invention, because the drainage port 110 is formed in the basement 100, there is no choice but to flow some water into the basement 100, If there is a risk that the electrical and mechanical equipment 10 may be damaged even by a slight inundation, the electrical and mechanical equipment 10 may be operated by the compressed air supply means 200 when the level of water introduced into the basement 100 is increased. It should be installed at a position higher than the bottom surface of the cellar 100 so as not to be submerged even if it rises to the starting height.

Therefore, the bottom surface of the basement 100, even if the water level introduced into the basement 100 is raised to a height at which the operation of the compressed air supply means 200 has a certain height so that the top surface is not submerged in water. , The base 130 is preferably provided with electrical and mechanical equipment 10 on the upper surface. As such, when the base 130 having a predetermined height is provided on the bottom surface of the basement 100, even if a certain amount of water flows into the basement 100, the electrical and mechanical equipment 10 is not submerged at all. There is an advantage that it is possible to more effectively prevent damage to the electrical and mechanical equipment (10).

Figure 4 is a cross-sectional view showing the submerged water level when the submerged underground structure is flooded according to the present invention.

As shown in FIG. 4, when the submersion prevention submerged structure according to the present invention is submerged, water is introduced into the basement 100 through the ventilation gallery 500, and a space provided between the two basements 100. (Space where a corridor or stairway is provided) is also filled with water and flows into the basement 100 through the communication hole 412 of the wire and the pipe entrance and exit 410.

The water introduced into the basement 100 is introduced into the basement 100 through the drainage port 110. When the level of the water introduced into the basement 100 rises to some extent as shown in FIG. 300 is operated to operate the compressed air air means (200). When the compressed air air means 200 is operated as described above, the basement 100 is filled with high-pressure air, and the water in the basement 100 is discharged to the outside through the drain hole 110. Of course, the water in the basement 100 may be discharged to the space provided between the two basements 100 through the wire and the pipe entrance 410.

In addition, when the water level of the water introduced into the basement 100 is lowered, the operation of the water level detecting means 300 is released, the compressed air air means 200 is stopped.

In this embodiment, the electrical and mechanical equipment 10 has been described in the embodiment of the distribution room and the machine room therein, the underground structure for flooding prevention according to the present invention to the various basements in addition to the distribution room and the machine room mentioned in this embodiment May also be applied.

As mentioned above, although this invention was demonstrated in detail using the preferable embodiment, the scope of the present invention is not limited to a specific embodiment, Comprising: It should be interpreted by the attached Claim. In addition, those skilled in the art should understand that many modifications and variations are possible without departing from the scope of the present invention.

1 is a cross-sectional view showing the structure of a conventional underground embedding distributor.

Figure 2 is a perspective view of the submerged underground structure according to the present invention.

3 is a cross-sectional view showing the internal configuration when the submerged underground structure according to the present invention is buried underground.

Figure 4 is a cross-sectional view showing the submerged water level when the submerged underground structure is flooded according to the present invention.

<Description of the symbols for the main parts of the drawings>

10: electrical and mechanical equipment 100: basement

110: drain port 120: ventilation port

130: base 200: compressed air supply means

300: water level detection means 400: electric wire and piping equipment

410: wires and piping entrance 500: ventilation gallery

510: outer vent 520: inner vent

Claims (7)

Basement 100 in which the through-hole drainage 110 is formed below the submerged water level; And Compressed air supply means for supplying compressed air into the basement 100 to discharge the water introduced into the basement 100 to the drain hole (110); Inundation prevention underground structure, characterized in that comprises a. The method of claim 1, It further comprises a water level detecting means for detecting the water level of the water introduced into the basement 100, The compressed air supply means 200 is a submerged underground structure, characterized in that it is operated to supply compressed air into the basement 100 when the water level of the water introduced into the basement 100 is raised above the set height. The method of claim 2, The basement 100 has a vent hole 120 formed on the side wall, Further comprising a ventilating gallery 500 having an outer vent 510 communicating with the outside, and an inner vent 520 communicating with the vent 120. The ventilation hole 120 and the inner ventilation hole 520 is formed at a position that is submerged in the water introduced into the basement 100 when the water level of the water introduced into the basement 100 rises above a predetermined height. Submerged structure to prevent flooding. The method of claim 2, Coupled to surround a plurality of wires and pipes 400 connected to the electrical and mechanical equipment 10, one end of the wires and pipe entrances 410 penetrating through the basement 100 into the basement 100, ), One end of the wire and the pipe entrance 410 is located at a point that is submerged in the water introduced into the basement 100 when the water level of the water flowing into the basement 100 rises above a set height. Underwater structure to prevent flooding. The method of claim 4, wherein The wire and the pipe entrance and exit 410, the underground structure for preventing flooding, characterized in that it has a through hole 412 formed in the upper side of the position higher than the drain port 110 for supplying the wire to the adjacent facility. The method of claim 2, The drainage port 110 is a submerged underground structure, characterized in that formed in a position to be submerged in the water introduced into the basement 100 when the water level of the water introduced into the basement 100 is higher than the set height. . The method of claim 2, The basement 100 includes a base 130 formed so that the upper surface is not submerged in the water introduced into the basement 100 when the water level of the water introduced into the basement 100 is raised to a predetermined height. , The electrical and mechanical equipment 10 is submerged underground structure, characterized in that installed on the upper surface of the base 130.

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