KR20250143491A - Dead water protecting apparatus - Google Patents

Abstract

The present invention discloses a water-prevention device. According to one embodiment of the present invention, the water-prevention device comprises: a main pipe having a hollow tube shape through which water flows and is divided into a plurality of sections and having an inner diameter that narrows; a plurality of venturi tubes provided in each of the plurality of sections inside the main pipe, the diameter of which narrows toward the center in the longitudinal direction; and an air supply tube connected to each of the plurality of venturi tubes and supplying air; wherein air is supplied to water flowing in the main pipe by the air supply tube, thereby generating a vortex, thereby preventing water-prevention.

Description

Dead Water Protection Apparatus

The present invention relates to a water-prevention device, and more particularly, to a water-prevention device capable of preventing the occurrence of water inside a water-flowing pipe.

Stagnant water generally refers to water that remains stagnant inside water tanks, water pipes, etc. without being discharged.

The water pipes connected to the water tank are made up of a main pipe and branch pipes with a smaller diameter than the main pipe and connected to the main pipe, and fire hoses, etc. are connected to the drainage ports of the branch pipes.

In addition, an on-off valve can be installed at the end of the branch pipe, a fire hose, etc. can be connected to the branch pipe, and the on-off valve can be opened to allow water to be discharged through the fire hose.

However, if a fire does not occur, the water may not be used for a long period of time, and the water inside the water pipes may stagnate for a long time without flowing.

Therefore, there is a problem that the water inside the water pipes may become contaminated by the contaminated water, or the contaminated water may be sprayed out when a fire hose is used, contaminating the surrounding area.

Korean Patent Publication No. 10-0729818 discloses a water pipe structure that activates the drainage of water.

However, the conventional technology has a problem in that air bubbles inside the device impede the drainage of the discharged water, resulting in poor drainage and resulting in water loss.

In addition, since the conventional technology is not effective in preventing gunshots, a technology that can improve the gunshot prevention effect is required.

Republic of Korea Patent No. 10-0729818

One embodiment of the present invention aims to provide a water-prevention device capable of preventing water leakage by preventing poor drainage in order to overcome the problems of the above-mentioned prior art.

According to one aspect of the present invention, there is provided a main pipe having a hollow tube shape through which water flows and is divided into a plurality of sections and has an inner diameter that narrows; a plurality of venturi tubes provided in each of the plurality of sections inside the main pipe and having a diameter that narrows toward the center in the longitudinal direction; and an air supply tube connected to each of the plurality of venturi tubes and supplying air; wherein air is supplied to water flowing through the main pipe by the air supply tube to generate a vortex, thereby preventing water from escaping.

In the multiple sections of the above main pipe having different diameters, a rotating section larger than the diameter of the main pipe is formed to allow water and air to mix.

At the drainage end of the above-mentioned pipe where water is discharged, a vortex-generating screw thread is formed to generate a vortex.

The above eddy current generating screw threads are provided with a blank section so that they are formed discontinuously.

The above blank section is provided with a vortex generating member that generates vortices.

The above air supply pipe is connected to the main pipe at an angle based on the side or plane.

The anti-shooting device according to the present invention has the following effects.

First, you can prevent water from saturating by supplying air to the water.

Second, it can improve the water-prevention effect by facilitating drainage.

Third, the anti-sniper effect can be significantly improved by maximizing the generation of eddies.

Figure 1 is a cross-sectional schematic diagram of an anti-shooting device according to one embodiment of the present invention.
Figure 2 is a plan schematic diagram of an anti-shooting device according to one embodiment of the present invention.

The embodiments described below are provided to facilitate a clear understanding of the technical concepts of the present invention by those skilled in the art, but are not intended to limit the scope of the present invention. Furthermore, the details depicted in the attached drawings are schematic drawings intended to facilitate the description of embodiments of the present invention and may differ from the actual implementation.

When it is said that a component is connected or connected to another component, it should be understood that it may be directly connected or connected to that other component, but there may also be other components in between.

FIG. 1 is a cross-sectional schematic diagram of an anti-shooting device according to one embodiment of the present invention, and FIG. 2 is a plan schematic diagram of an anti-shooting device according to one embodiment of the present invention.

Referring to FIGS. 1 and 2 together, an anti-shooting device (100) according to one embodiment of the present invention is configured to include a main pipe (110), a venturi pipe (120), and an air supply pipe (130).

The main body (110) is a hollow tube-shaped body through which water flows and is divided into multiple sections.

The plurality of sections of the main pipe (110) are structured such that their internal diameters narrow from the inlet end (110-2) where water flows in toward the drain end (110-4) where water is discharged. For example, the internal diameters of the plurality of sections of the main pipe (110) are formed from the inlet end (110-2) toward the drain end as D1, D2 having a diameter smaller than D1, and D3 having a diameter smaller than D2, and may be configured to have a greater number of diameter differences than this.

The outer diameter of the main body (110) may have the same diameter or may be smaller depending on the inner diameter.

In each of the plurality of sections of the main pipe (110) having different diameters, a rotating section (112) larger than the inner diameter of the main pipe (110) is formed to allow water and air to mix. It is preferable that the diameter of the rotating section (112) be larger than the outer diameter of the main pipe (110).

Inside the drain end (110-4) from which water of the main body (110) is discharged, a vortex-generating screw thread (114) that generates a vortex is formed.

The vortex-generating screw thread (114) is provided with a blank section (114-2) so that the screw threads are formed discontinuously along the length direction of the main pipe (110). The blank section (114-2) is provided with a vortex-generating member (116) that generates a vortex. The vortex-generating member (116) may have, for example, a cross shape when viewed from the direction of water flow, and is not limited to a specific shape as long as it has a structure that generates a vortex.

The venturi tube (120) is configured to include a plurality of venturi tubes, for example, a first venturi tube (121), a second venturi tube (122), and a third venturi tube (123), each having a different diameter in a plurality of sections within the main tube (110). Each venturi tube has a structure in which the diameter narrows from both ends toward the center, and the inner diameter is minimum in the narrow section of the center where water flows, and air is supplied.

The air supply pipe (130) is configured to include a plurality of air supply pipes, for example, a first air supply pipe (131), a second air supply pipe (132), and a third air supply pipe (133), and is connected to a plurality of venturi tubes (120) to supply air. It is preferable that the end of the air supply pipe (130) that supplies air is connected to a narrow portion in the center of the venturi tube (120) to supply air.

The first air supply pipe (131) is connected vertically to the main pipe (110), and the second air supply pipe (132) and the third air supply pipe (133) are connected to the main pipe (110) at an angle relative to the side or plane. That is, it is preferable that the second air supply pipe (132) is connected at an angle to the left from the longitudinal center line (C-C) of the main pipe (110) relative to the plane, and the third air supply pipe (133) is connected at an angle to the right from the longitudinal center line (C-C) of the main pipe (110).

Referring to FIGS. 1 and 2 together, the operational relationship of the anti-water device (100) according to one embodiment of the present invention will be described. Water is supplied from the inlet end (110-2) of the main pipe (110). The water flows from the inlet end (110-2) of the main pipe (110) toward the drain end (110-4) through which water is discharged.

The main body (110) is divided into multiple sections whose diameters narrow from the inlet end (110-2) toward the drain end (110-4).

First, water flows through the main pipe (110), and air is supplied by the first air supply pipe (131) from the first narrow section (121-2) of the first venturi pipe (121) provided in the section of the main pipe (110) with a diameter of D1.

The water supplied with air has a vortex that increases in the rotation section (112) larger than the inner diameter of the main pipe (110), thereby improving the mixing of water and air.

Continuing, air is supplied to the flowing water by the second air supply pipe (132) from the second narrow section (122-2) of the second venturi pipe (122) provided in the section where the diameter of the main pipe (110) is D2, which is smaller than D1.

Here, the second air supply pipe (132) is inclined to the left from the longitudinal center line (C-C) of the main pipe (110), thereby increasing the generation of vortex.

The water supplied with air passing through the second venturi tube (122) has its vortex increased through the rotation section (112), thereby further improving the mixing of water and air.

Next, air is supplied to the water passing through the second venturi tube (122) by the third air supply tube (133) from the third narrow section (123-2) of the third venturi tube (123) provided in the section where the diameter of the main tube (110) is D3, which is smaller than D2.

The third air supply pipe (133) is inclined to the right from the longitudinal center line (C-C) of the main pipe (110), which further increases the generation of vortex.

In this way, water that has passed through multiple venturi tubes (121, 122, 123) provided inside the main body (110) is mixed with air and discharged through the drain end (110-4).

Here, a vortex-generating screw thread (114) that generates a vortex is formed at the drain end (110-4) of the main body (110).

The eddy current generating screw thread (114) has a discontinuously formed screw thread shape, and a eddy current generating member (116) that further increases eddy current generation is provided in the blank section (114-2) where the screw thread is not formed.

Water passing through the cross-shaped vortex generating member (116) passes through the vortex generating screw thread (114) formed at the rear end of the main pipe (110), thereby further increasing the generation of vortices.

Therefore, the water prevention device according to the present invention can prevent water from being washed away by supplying air to water to facilitate drainage, and can significantly improve the water prevention effect by maximizing the generation of eddies.

Those skilled in the art will appreciate that the present invention can be implemented in other specific forms without changing the technical spirit or essential characteristics thereof. Therefore, the embodiments described above are merely the most preferable embodiments selected from among various possible embodiments to aid understanding by those skilled in the art, and the technical spirit of the present invention is not necessarily limited or restricted to the presented embodiments, and various changes, additions, and modifications are possible within the scope of the technical spirit of the present invention, and it is to be understood that other equivalent embodiments are possible.

100: Anti-shooter device
110: Subjective
110-2: Inlet end
110-4: Drainage end
112: Rotation section
114: Vortex generating screw thread
114-2: Blank section
116: Absence of eddy current generation
120: Venturi tube
121: First Venturi tube
121-2: 1st narrow section
122: Second Venturi tube
122-2: Second narrow section
123: Third Venturi Tube
123-2: Third Narrow Section
130: Air supply pipe
131: First air supply pipe
132: Second air supply pipe
133: Third air supply pipe

Claims (6)

A main pipe is a hollow tube-shaped structure through which water flows, and is divided into multiple sections with an inner diameter that narrows;
A plurality of venturi tubes each provided in a plurality of sections inside the above-mentioned main body and having a diameter that narrows toward the center in the longitudinal direction; and
An air supply pipe connected to each of the plurality of venturi tubes to supply air;
The above-mentioned subject is characterized in that air is supplied to the water flowing through the air supply pipe, thereby generating a vortex, thereby preventing water from escaping.
Anti-shooting device. In the first paragraph,
In the above-mentioned main pipe, a plurality of sections having different diameters are formed with a rotating section larger than the diameter of the main pipe so that water and air are mixed.
Anti-shooting device. In the first paragraph,
The drain end of the above-mentioned main pipe is characterized in that a vortex-generating screw thread is formed to generate a vortex.
Anti-shooting device. In the third paragraph,
The above eddy current generating screw thread is characterized in that a blank section is provided so that it is formed discontinuously.
Anti-shooting device. In paragraph 4,
The above blank section is characterized in that a vortex generating member that generates a vortex is provided.
Anti-shooting device. In the first paragraph,
The above air supply pipe is characterized in that it is connected to the main pipe at an angle based on the side or plane.
Anti-shooting device.