KR102368680B1 - Plumbing equipment of fire water for architecture - Google Patents

Abstract

The present invention relates to a firefighting water supply and drainage apparatus for construction. More specifically, the firefighting water supply and drainage apparatus for the construction of the present invention comprises: a firefighting water tank; a boundary stone; a first rainwater inlet pipe; a second rainwater inlet pipe; a water intake unit; a supply pipe; a firefighting water sump; and a hollow drainage unit. According to the present invention, discarded water resources can be recycled as a firefighting water.

Description

Plumbing equipment of fire water for architecture

The present invention relates to a fire-fighting water supply and drainage system, and more particularly, to a fire-fighting water supply and drainage system for buildings that can purify rainwater and collect it underground and reuse rainwater collected underground in case of a fire in a building.

In general, the water supply method of buildings is to be used by sending it to a water tank installed on the roof of the building, which is supplied to the building through a water supply pipe, and then storing it in the water tank.

In this case, it is typically configured to supply fire water by connecting it to a sprinkler facility installed in the interior of a building using a water tank.

Meanwhile, in recent years, large-scale earthquakes have occurred in various regions of the world, causing damage to many lives and property.

When such a large-scale earthquake occurs and the infrastructure is destroyed, the supply of water through the water supply pipe is interrupted, so when a fire occurs in a building, it is difficult to quickly respond to the fire.

In other words, since Korea is not a safe area against large-scale earthquakes, it is necessary to prepare for these problems.

Korean Patent Publication No. 10-1662267 (Announced on October 05, 2016)

The problem of the present invention devised to solve the above problems is to purify and collect rainwater through a firefighting water supply tank in which a filter medium is formed in a multi-layered structure, and in the event of a fire in a building, the collected rainwater is supplied to a sprinkler installed inside the building. is to provide a fire-fighting water supply and drainage system for construction that can recycle water resources into fire-fighting water.

The present invention, which has been devised to achieve the above object, is a fire water supply and drainage device for construction, which is formed by digging the ground on the outer side of the building to a predetermined depth based on the building. A soil cement layer formed, a sand layer having a particle diameter of about 2 mm to about 3 mm formed at a predetermined height above the soil cement layer formed on the bottom surface of the underground space, and a predetermined height above the sand layer Firefighters having an activated carbon layer, a gravel layer having a particle diameter of about 5 mm to about 6 mm formed at a certain height on the upper side of the activated carbon layer, and a shielding plate seated horizontally on the upper surface of the gravel layer to shield the opening of the underground space A water supply tank, a boundary stone that is installed on the ground outside the edge of the opening of the fire water supply tank, and has a through hole horizontally penetrating the inside so that rainwater falling to the ground flows into the fire water water supply tank, one end inside the through hole formed in the boundary stone The interference fit is inserted, and the other end penetrates the shield plate of the fire water supply tank vertically and is inserted into the gravel layer of the fire water water tank. One end is connected to the eaves gutter through which rainwater is collected, and the other end penetrates vertically through the shielding plate of the firefighting water supply tank and is inserted into the gravel layer of the firefighting water supply tank. is vertically buried in a fire water supply tank with the upper end exposed to the outside through And rainwater flowing into the fire water supply tank through the second rainwater inlet pipe is purified while passing through the gravel layer, the activated carbon layer, and the sand layer in turn, and the fire water collected in the sand layer flows into the internal space through the collection hole A hollow water intake section, which penetrates the outer wall of the building and is installed on the bottom of the inner slab of the building, has one end in the opening formed in the water intake section Fire water collected in the inner space of the water intake is connected to this connection, and the supply pipe equipped with a sprinkler to spray fire water into the interior of the building is provided on the outer side, and the ground on the other side of the outside of the building is dug to a certain depth based on the building. The soil cement layer formed to a predetermined thickness on the bottom surface and the inner surface of the underground space formed by the above, and the particle diameter formed at a predetermined height above the soil cement layer formed on the bottom surface of the underground space is about 2 mm to about 3 mm A firefighter having a sand layer, a gravel layer having a particle diameter of about 5 mm to about 6 mm formed at a predetermined height above the sand layer, and a shielding plate seated horizontally on the upper surface of the gravel layer to shield the opening of the underground space Penetrates vertically through the water sump and the shielding plate of the fire water sump and is vertically buried in the fire water sump with the upper end exposed to the outside. is formed, and the fire water is drained into the inner space through the other end of the supply pipe connected to the opening, and the fire water is drained into the gravel layer of the fire water sump through the drain hole.

It is buried in the lower ground of the building, and includes a hollow return pipe connecting the fire water drainage tank and the fire water supply tank to each other, and one end of the return pipe is connected to the lower outer surface of the fire water drainage tank, and multiple stages of the return pipe is connected to the lower outer surface of the fire water supply tank, and sand having a particle diameter of about 2 mm to about 3 mm is accommodated inside the return pipe, and the return pipe is inclined downward at a predetermined angle toward the fire water supply tank. It is characterized in that it is buried underground.

The water intake unit has a pointed cone shape at a lower end, a spiral protrudes along the outer diameter, and a hollow water intake pipe with open top and bottom communicating with the opening is provided in the inner space, and extends radially horizontally from the upper edge to the It is characterized in that the seating wing is formed to be seated on the upper surface of the shielding plate of the fire fighting water supply tank, and the lower portion where the water collecting hole is formed is buried in the sand layer of the fire water supply tank.

The drainage unit is formed in the form of a pointed cone at the lower end, a spiral protrudes along the outer diameter, is buried in the gravel layer of the fire fighting water sump, and extends radially horizontally from the upper edge to be seated on the upper surface of the shielding plate of the fire water sump It is characterized in that the seat wing is formed.

The present invention purifies and collects rainwater through a fire-fighting water supply tank in which a filter medium is formed in a multi-layered structure, and supplies the collected rainwater to a sprinkler installed inside the building when a fire occurs in the building. .

1 is a conceptual diagram showing a fire water supply/discharge device for construction according to an embodiment of the present invention;
2 is a cross-sectional view showing a fire-fighting water supply tank in the fire-fighting water supply/discharge device for construction according to an embodiment of the present invention;
3 is a cross-sectional view showing a fire water drainage tank in the fire water supply and discharge device for construction according to an embodiment of the present invention;
4 is a cross-sectional view of an operating state of the fire water supply/discharge device for construction according to an embodiment of the present invention;
5 is an external perspective view showing a water intake unit in the fire water supply/discharge device for construction according to an embodiment of the present invention;
6 is a cross-sectional view of FIG. 5;
7 is an external perspective view showing a drainage unit in the fire water supply and drainage device for construction according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the fire-fighting water supply/discharge device for construction according to the present invention will be described in detail.

1 is a conceptual diagram showing a fire fighting water supply and drainage device for construction according to an embodiment of the present invention, FIG. 2 is a cross-sectional view showing a fire fighting water supply tank in a fire water supply and drainage system for a building according to an embodiment of the present invention, and FIG. A cross-sectional view showing a fire water drainage tank in a fire water supply/discharge device for construction according to an embodiment, FIG. 4 is a cross-sectional view showing a fire water supply/discharge device for construction according to an embodiment of the present invention, and FIG. It is an external perspective view showing the water intake unit in the fire water supply/discharge device for construction, FIG. 6 is a cross-sectional view of FIG. 5, and FIG. 7 is an external perspective view showing the drainage unit in the fire water supply/discharge unit for construction according to an embodiment of the present invention.

1 to 7 , the fire water supply and drainage device for construction according to a preferred embodiment of the present invention includes a fire water supply tank 100 , a boundary stone 200 , a first rainwater inlet pipe 300 , and a second rainwater inlet pipe 400 , the water intake unit 500 , the supply pipe 600 , the fire water drainage tank 700 and the components including the drainage unit 800 , which will be described in detail as follows.

The firefighting water supply tank 100 is formed in the basement on one side of the outside of the building 10 based on the building 10 , and various pollutants contained in the rainwater as rainwater flows into the inside through the upper surface of the firefighting water supply tank 100 . It is to purify rainwater by filtration and at the same time collect the purified rainwater and use it as a firefighting water.

The soil cement layer 110 is formed at a predetermined height on the inner bottom surface of the underground space A1, and the soil cement layer 110 is formed with a predetermined thickness on the inner surface of the underground space A1.

Here, the soil cement mixes the cement with soil and water so that the bottom and inner surfaces of the underground space part A1 of the fire water supply tank 100 are hardened so that the ground and the side surfaces of the underground space part A1 are firmly compacted. As such, it serves to prevent the moisture seeping into the fire water supply tank 100 from penetrating the soil cement layer 110 , so that the purified rainwater is stored inside the soil cement layer 110 .

In addition, the sand layer 120 is formed at a predetermined height above the soil cement layer 110 formed on the bottom surface of the underground space A1. The sand layer 120 serves as a filter medium for filtering rainwater, and each particle has a diameter of about 2 mm to less than about 3 mm.

In addition, the activated carbon layer 130 is formed at a predetermined height above the sand layer 120 . The activated carbon layer 130 serves to adsorb and remove various contaminants included in rainwater, and the activated carbon is known to have excellent adsorption and deodorization performance of residual chlorine, organic matter.

Finally, the gravel layer 140 is formed at a predetermined height on the upper side of the activated carbon layer 130 . The gravel layer 140 serves as a filter medium for filtering rainwater, and each particle has a size of about 5 mm to about 6 mm, which is larger than the diameter of the sand constituting the sand layer 120 .

That is, the rainwater that is primarily filtered while passing through the gravel layer 140 of the uppermost layer of the fire water supply tank 100 is purified while passing through the activated carbon layer 130 below it, and passing through the sand layer 120 below it. The filtered rainwater that is secondarily filtered and finally does not pass through the soil cement layer 110 of the bottom and inner surfaces of the firefighting water supply tank 100 is stored in the sand layer 120 .

In addition, the fire water supply tank 100 includes a shielding plate 150 that is horizontally seated on the upper surface of the gravel layer 140 and shields the opening of the underground space A1.

The boundary stones 200 are installed long in the longitudinal direction of the road along the edge of the road, and are installed in a state where both ends of each unit boundary stones are in contact with each other.

The boundary stone 200 serves to separate the road and the sidewalk, but also serves to prevent rainwater from the road from passing over to the building 10 during heavy rain.

On the other hand, the boundary stone 200 of the present invention is seated and installed on the ground outside the edge of the opening of the fire water supply tank 100, and horizontally penetrates the inside so that rainwater falling to the ground flows into the fire water water supply tank 100. A through hole 210 is formed.

The first rainwater inlet pipe 300 serves to guide rainwater flowing into the firefighting water supply tank 100 through the through hole 210 formed in the boundary stone 200 into the firefighting water supply tank 100 . This first rainwater inlet pipe 300, both ends are open and made of a hollow hollow form.

In other words, the open end of the first rainwater inlet pipe 300 is press-fitted into the inside of the through hole 210 formed in the boundary stone 200 , and the open other end of the first rainwater inlet pipe 300 is supplied with firefighting water. It is inserted into the gravel layer 140 of the fire-fighting water supply tank 100 by vertically penetrating the shielding plate 150 of the tank 100 .

The second rainwater inlet pipe 400 serves to guide rainwater falling on the roof of the building 10 into the firefighting water supply tank 100 . This second rainwater inlet pipe 400, both ends are open and made in the form of a hollow hollow.

In other words, the second rainwater inlet pipe 400 is installed vertically on the outer wall of the building 10 , and the open end of the second rainwater inlet pipe 400 collects rainwater falling to the roof of the building 10 . The other end of the second rainwater inlet pipe 400, which is connected to the eaves gutter 11 that becomes the is inserted

In the water intake unit 500, rainwater flowing into the fire fighting water supply tank 100 through the first rainwater inlet pipe 300 and the second rainwater inlet pipe 400 is transferred to the gravel layer 140, the activated carbon layer 130, and the sand. This is to take in the fire water that has been purified by the fire water supply tank 100 and stored in the sand layer 120 while passing through the layers 120 in turn. It is vertically propelled and buried in the fire water supply tank 100 with the upper end exposed to the outside.

At this time, the upper end of the water intake unit 500 is buried in the fire water supply tank 100 in a state exposed to the outside from the upper surface of the fire water supply tank 100 .

Here, the water intake unit 500 is made of a hollow, hollow shape provided with an internal space and a conical shape with a sharp lower end.

In addition, a spiral 520 is formed to protrude along the outer diameter of the water intake unit 500 , and an opening is formed in the center of the upper surface of the water intake unit 500 in a vertical direction.

Since the lower end of the water intake unit 500 has a sharp conical shape, the water intake unit 500 can be easily propelled to the fire water water supply tank 100, and the spiral 520 is formed to protrude along the outer diameter of the fire water water supply tank ( Even when an external force is applied in the opposite direction to the buried direction in the state buried in 100 ), the water intake unit 500 can be maintained vertically and firmly fixed to the fire water supply tank 100 due to the spiral 520 .

In addition, a plurality of water collecting holes 510 are formed in the lower outer surface of the water intake unit 500 . Rainwater stored in the sand layer 120 after being filtered and purified while passing through the gravel layer 140 , the activated carbon layer 130 , and the sand layer 120 sequentially through the collecting hole 510 is inside the water intake unit 500 . it enters the space.

That is, the lower portion of the water intake unit 500 in which the water collection hole 510 is formed is buried in the sand layer 120 of the fire water supply tank 100 , so that rainwater purified fire water flows into the water intake unit 500 .

In addition, in the inner space of the water intake unit 500 , a hollow water intake pipe 530 with open top and bottom communicating with the opening formed on the upper surface is integrally provided. The fire water collected in the inner space of the water intake unit 500 is taken in through the water intake pipe 530 .

At this time, the supply pipe 600 exposed to the ground is connected to the opening formed on the upper surface of the water intake unit 500 .

Here, the outer surface of the water intake pipe 530 does not contact the inner surface of the water intake unit 500 , and the lower end of the water intake pipe 530 does not contact the inner lower surface of the water intake unit 500 .

On the other hand, a seating wing 540 extending radially horizontally from the upper edge of the water intake unit 500 exposed to the ground and seated on the upper surface of the shielding plate 150 of the fire fighting water supply tank 100 may be formed.

It is possible to prevent the water intake unit 500 from sinking due to the seating blades 540, and rotate the water intake unit 500 while the operator grips the seating blades 540 to receive water into the fire water supply tank 100. The unit 500 may be vertically propelled.

The supply pipe 600, in the form of a hollow hollow with both ends open, penetrates the outer wall of the building 10 and is installed on the bottom of the inner (indoor) slab 12 of the building 10 . In addition, one end of the supply pipe 600 is connected to an opening formed in the water intake unit 500 vertically buried in the fire water supply tank 100 to receive the fire water collected in the internal space of the water intake unit 500 .

A sprinkler 610 is mounted on the outer surface of the supply pipe 600 so that fire water is sprayed into the interior of the building 10 in case of fire.

Here, a pump is provided between the opening formed on the upper surface of the water intake unit 500 and the supply pipe 600 , and the fire water collected in the water intake unit 500 by the pump is forcibly pumped upward.

The fire water drainage tank 700 is formed in the ground on the other side of the outside of the building 10 based on the building 10 , and the fire water drained through the other open end of the supply pipe 600 is the upper surface of the fire water drainage tank 700 . It is to purify the fire water by re-filtering the fire water as it flows into the interior through the evaporator, and at the same time collect the purified fire water and recycle it as fire water. .

The soil cement layer 710 is formed at a predetermined height on the inner bottom surface of the underground space A2, and the soil cement layer 710 is formed with a predetermined thickness on the inner surface of the underground space A2.

Here, the soil cement mixes the cement with soil and water so that the bottom surface and the inner surface of the underground space part A2 of the fire water drainage tank 700 are hardened so that the ground and the side surfaces of the underground space part A2 are firmly compacted. As such, it serves to prevent the moisture permeating into the fire water drainage tank 700 from penetrating the soil cement layer 710 , so that the purified fire water is stored inside the soil cement layer 710 .

In addition, a sand layer 720 is formed at a predetermined height above the soil cement layer 710 formed on the bottom surface of the underground space A2. The sand layer 720 serves as a filter medium for filtering firefighting water, and each particle has a diameter of about 2 mm to less than about 3 mm.

Then, the gravel layer 740 is formed at a predetermined height on the upper side of the sand layer 720 . The gravel layer 740 serves as a filter medium for filtering firefighting water, and each particle has a size of about 5 mm to about 6 mm, which is larger than the diameter of the sand constituting the sand layer 720 .

That is, the fire water that is first filtered while passing through the gravel layer 740 of the uppermost layer of the fire water sump 700 is secondary filtered while passing through the sand layer 720 below it, and finally the fire water sump 700 The filtered fire water that does not pass through the floor and the inner soil cement layer 710 is stored in the sand layer 720 .

In addition, the fire water drainage tank 700 includes a shielding plate 750 that is horizontally seated on the upper surface of the gravel layer 740 to shield the opening of the underground space A2.

At this time, the height of the bottom surface of the fire water drainage tank 700 is formed to be higher than the height of the bottom surface of the fire water supply tank 100 .

The drainage unit 800 is for returning the fire water drained from the supply pipe 600 , and vertically penetrates the shield plate 750 of the fire water drainage tank 700 to expose the upper end of the fire water drainage tank to the outside. It is propelled vertically to 700 and is buried.

At this time, the upper end of the drain unit 800 is buried in the fire water drain tank 700 in a state exposed to the outside from the upper surface of the fire water drain tank 700 .

Here, the drainage unit 800 is formed in the form of a hollow hollow in which an inner space is provided and a conical shape with a sharp lower end.

In addition, a spiral 820 is formed to protrude along the outer diameter of the drainage unit 800 , and an opening is formed in the center of the upper surface of the drainage unit 800 in a vertical direction.

Since the lower end of the drainage unit 800 has a sharp cone shape, the drainage unit 800 can be easily propelled to the fire water drainage cistern 700, and since the spiral 820 protrudes along the outer diameter, the fire water drainage cistern ( Even when an external force is applied in the direction opposite to the direction in which it is buried in the state of being buried in the 700), it is possible to maintain the state in which the drainage unit 800 is vertically and firmly fixed to the fire water sump 700 due to the spiral 820 .

In addition, a plurality of drain holes 810 are formed on the outer surface of the drain unit 800 .

In other words, the fire water drained through the other open end of the 600 of the supply pipe 600 connected to the upper surface opening formed in the drainage unit 800 is drained into the internal space of the drainage unit 800, and the drainage unit 800. Since the vertical length of the water intake unit 500 is shorter than that of the water intake unit 500 , the fire water penetrates into the gravel layer 740 through the drainage hole 810 formed on the outer surface of the drainage unit 800 .

On the other hand, a seating wing 840 extending radially horizontally from the upper edge of the drain part 800 exposed to the ground and seated on the upper surface of the shield plate 750 of the fire water drain tank 700 may be formed.

It is possible to prevent the drainage unit 800 from sinking due to the seating blades 840, and the worker rotates the drainage unit 800 while holding the seating blades 840 to drain the water into the fire water drainage tank 700. The unit 800 may be propelled vertically.

On the other hand, the present invention may be configured to further include a water exchange pipe 900 that is buried in the lower ground of the building 10 and connects the fire water drainage tank 700 and the fire water water supply tank 100 to each other.

The return pipe 900 is to re-supply the fire water filtered through the fire water drainage tank 700 to the fire water water supply tank 100 to recycle the fire water through the fire water water supply tank 100 .

In other words, the return pipe 900 is in the form of a hollow hollow with both ends open, and the open end of the return pipe 900 is connected to the lower outer surface of the fire water drainage tank 700, and the return pipe 900 The open multi-stage of the is connected to the lower outer surface of the fire water supply tank (100). At this time, the sand 910 having a particle diameter of about 2 mm to about 3 mm is accommodated in the return pipe 900 to filter the transferred fire water.

Here, the water return pipe 900 is buried underground in a state inclined downward at a predetermined angle toward the fire water supply tank 100 . This is to allow the fire water stored in the sand layer 720 of the fire water drainage tank 700 to naturally flow into the sand layer 120 of the fire water water supply tank 100 through a fall.

In the above, the present invention has been described based on a preferred embodiment, but the technical spirit of the present invention is not limited thereto, and it is possible to make modifications or changes within the scope described in the claims. Those of ordinary skill in the art to which the present invention pertains It is apparent to the user, and such modifications or changes shall fall within the scope of the appended claims.

10: Building 11: Eaves gutter
12: inner slab 100: fire water tank
110, 710: earth cement layer 120, 720: sand layer
130: activated carbon layer 140, 740: gravel layer
150, 750: shield plate 200: boundary stone
210: through hole 300: first rainwater inlet pipe
400: second rainwater inlet pipe 500: water intake
510: catchment hole 520, 820: spiral
530: intake pipe 540, 840: seat wing
600: supply pipe 610: sprinkler
700: fire water sump 800: drain
810: drain hole 900: return pipe
910: sand A1, A2: geospatial part

Claims (4)

A soil cement layer formed to a predetermined thickness on the bottom surface and an inner surface of the underground space formed by digging the ground on the outside of the building to a predetermined depth based on the building, and the soil cement layer formed on the bottom surface of the underground space A sand layer having a particle diameter of 2 mm to 3 mm formed at a predetermined height above the sand layer, an activated carbon layer formed at a predetermined height above the sand layer, and a particle diameter formed at a predetermined height above the activated carbon layer having a particle diameter of 5 mm to 6 mm a fire water supply tank having a gravel layer and a shielding plate that is horizontally seated on the upper surface of the gravel layer to shield the opening of the underground space;
a boundary stone installed on the ground outside the edge of the opening of the fire fighting water supply tank and having a through-hole horizontally penetrating the inside so that rainwater falling to the ground flows into the fire water water supply tank;
A first hollow rainwater inlet pipe having one end inserted into the through hole formed in the boundary stone and the other end vertically penetrating the shield plate of the fire fighting water supply tank and inserted into the gravel layer of the fire water supply tank;
It is installed vertically on the outer wall of the building, one end is connected to the eaves gutter that collects rainwater falling onto the roof of the building, and the other end is a hollow inserted into the gravel layer of the fire water supply tank by penetrating the shield plate of the fire fighting water tank vertically. of the second rainwater inlet pipe;
Penetrates the shield plate of the fire water supply tank vertically and is vertically buried in the fire water supply tank with the upper end exposed to the outside. The rainwater flowing into the fire water supply tank through the first rainwater inlet pipe and the second rainwater inlet pipe is purified while passing through the gravel layer, the activated carbon layer, and the sand layer in turn, and the fire water collected in the sand layer is the house. a hollow water intake unit introduced into the inner space through the water hole;
It penetrates the outer wall of the building and is installed on the bottom surface of the inner slab of the building, and one end is connected to the opening formed in the water intake unit to supply fire water collected in the inner space of the water intake unit, and fire water is sprayed into the interior of the building on the outer side supply piping equipped with sprinklers that
An earth cement layer formed to a predetermined thickness on the bottom surface and an inner surface of the underground space part formed by digging the ground on the other side of the building to a predetermined depth based on the building, and the soil cement layer formed on the bottom surface of the underground space part A sand layer with a particle diameter of 2 mm to 3 mm formed at a predetermined height above the a fire water drainage tank having a shielding plate for shielding the opening of the space; and
Penetrates the shield plate of the fire water sump vertically and is vertically buried in the fire water sump with the upper end exposed to the outside, an inner space is provided, an opening is formed in the center of the upper surface, and a plurality of drain holes are formed on the outer surface, , A hollow drainage part through which the fire water is drained into the inner space through the other end of the supply pipe connected to the opening and the fire water is drained to the gravel layer of the fire water sump through the drain hole; and
It includes; a hollow return pipe buried in the lower ground of the building and connecting the fire water drainage tank and the fire water water supply tank to each other;
Sand having a particle diameter of 2 mm to 3 mm is accommodated in the return pipe to filter the fire water transferred from the fire water drainage tank to the fire water supply tank,
The water intake unit extends radially horizontally from the upper edge to form a seating wing that is seated on the upper surface of the shielding plate of the fire fighting water supply tank,
The drainage unit extends horizontally radially from the upper edge to form a seating wing that is seated on the upper surface of the shielding plate of the fire water drainage tank. According to claim 1,
One end of the return pipe is connected to the lower outer surface of the fire fighting water sump, and multiple ends of the return pipe are connected to the lower outer surface of the fire water supply tank,
The water return pipe is a fire water supply and drainage device for construction, characterized in that it is buried in the ground in a downwardly inclined state at a predetermined angle toward the fire water supply tank. According to claim 1,
The intake unit,
The lower end is made in the shape of a pointed cone, a spiral is protruded along the outer diameter, and the inner space is provided with a hollow water intake pipe with open top and bottom communicating with the opening, and the lower portion where the water collection hole is formed is in the sand layer of the fire water supply tank. Fire water supply and drainage device for construction, characterized in that it is buried. According to claim 1,
The drain unit,
Fire water supply and drainage device for construction, characterized in that the lower end is made in the shape of a pointed cone, a spiral is formed to protrude along the outer diameter, and is buried in the gravel layer of the fire water sump.

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