KR20240056081A - Sprinkling device to remove drainage foam in power plant - Google Patents

Abstract

The present invention relates to a sprinkler device for removing drainage foam from power plants. More specifically, it detects the level of seawater according to the ebb and flow of the tide and automatically controls the operation of the seawater pump, thereby preventing the breakdown of the sprinkler device for removing drainage foam from power plants. and a sprinkler device for removing drainage foam from power plants to prevent damage.
For this purpose, a seawater pump is installed on a structure above the seawater and is installed to generate pumping force; A seawater suction pipe installed on one side of the seawater pump and providing a conduit through which seawater is sucked by the suction force of the drive pump; a seawater discharge pipe installed on the other side of the seawater pump and providing a conduit through which seawater is discharged toward the drainage foam; A spray nozzle installed at the end of the seawater discharge pipe to spray seawater toward the drainage bubbles; and a seawater level detection means installed in the seawater suction pipe to detect changes in seawater level.

Description

Sprinkling device to remove drainage foam in power plant}

The present invention relates to a sprinkler device for removing drainage foam from power plants, and more specifically, to a sprinkler device for removing drainage foam from power plants that senses the level of seawater according to the ebb and flow of the tide and automatically controls the operation of the seawater pump. It's about.

When seawater is used as cooling water in a power plant, a lot of foam is generated at the seawater outlet, and the drainage foam affects the operation of power generation facilities. This occurs due to the stickiness of organic substances contained in large quantities in seawater. It occurs in sections where air is introduced by turbulent currents generated at all seawater outlets, such as seawalls, tidal power plants, power plants, and small hydro power outlets, and at bridge piers and It can also be caused by sleep loss. In particular, when seawater is used as cooling water and discharged from the cooling water drains of plant facilities such as tidal power plants, power plants, and small hydro power plants, a lot of foam is generated in the drains. This drainage foam causes visual pollution, and some of the drainage foam generated when seawater is drained is discharged into nearby fish farms or coastal beaches, frequently raising complaints from residents. Therefore, various methods have been proposed to reduce foam when draining coolant.

Conventionally, in order to reduce drainage foam generated when draining seawater used as cooling water in plant facilities, a method of injecting antifoaming agent or using a foam fence to induce natural disappearance after retention for a certain period of time has been proposed. However, when mixing antifoaming agents at the water intake stage, there is a problem of limited use due to the cost of adding chemicals and the impact on the environment. To solve this problem, when draining cooling water, water is sprayed on the drainage foam collected in the power plant's blocking membrane to reduce the foam and prevent the foam from flowing into the sea. In other words, when water is sprayed on the drainage foam, the water surface cools instantly and the bubbles burst and disperse, causing the foam to disappear. The present applicant has filed an application for a watering system for foam removal through 『Power Plant Drainage Foam Removal Apparatus and Method (Prior Document Korea Publication No. 10-2019-0114443)』. However, the above-mentioned prior art literature has a problem in that it is difficult to effectively pump seawater when the seawater level changes due to tidal ebb and flow. In other words, even when the seawater level is low, seawater is sucked in and sprayed into the foam, so there is a problem of not only failure of the sprinkler device, but also damage to the sprinkler device. This is because, when the seawater level is low, not only seawater but also air may be mixed, causing mechanical damage to the sprinkler device.

Republic of Korea Publication No. 10-2019-0114443

The present invention was devised to solve the above-mentioned problems, and the purpose of the present invention is to remove bubbles from the cooling water drained from the power plant by automatically controlling the seawater pumping operation while responding to changes in the water level of the seawater according to the ebb and flow of the tide. The purpose is to provide a sprinkler system for removing drainage foam from power plants so that the sprinkler system can operate stably.

In order to achieve the above object, the present invention includes a seawater pump installed on a structure above seawater and capable of generating pumping force; A seawater suction pipe installed on one side of the seawater pump and providing a conduit through which seawater is sucked by the suction force of the drive pump; a seawater discharge pipe installed on the other side of the seawater pump and providing a conduit through which seawater is discharged toward the drainage foam; A spray nozzle installed at the end of the seawater discharge pipe to spray seawater toward the drainage bubbles; and a seawater level detection means installed in the seawater intake pipe to detect changes in the seawater level.

At this time, the spray nozzle is preferably installed so that it can rotate in the seawater discharge pipe.

Additionally, it is preferable that a strainer is installed at the lower end of the seawater intake pipe.

The sprinkler device for removing drainage bubbles in a power plant according to the present invention provides a seawater level detection means that constantly detects changes in the seawater level based on the seawater intake pipe, so that the operation of the seawater pump can be automatically controlled. In other words, the present invention has the effect of preventing failure and damage to the sprinkler device for removing drainage foam by automatically stopping the operation of the seawater pump when the seawater level is low.

Figure 1 is a configuration diagram showing a sprinkler device for removing drainage foam from a power plant according to a preferred embodiment of the present invention.
Figure 2 is a diagram showing a sprinkler device for removing drainage foam from a power plant according to a preferred embodiment of the present invention.

Terms or words used in this specification and claims are not to be construed limited to their ordinary or dictionary meanings, and the inventor can appropriately define the concept of terms to explain his or her invention in the best way. It must be interpreted based on the meaning and concept consistent with the technical idea of the present invention.

Hereinafter, a sprinkler device (hereinafter referred to as 'sprinkler device') for removing drainage foam from a power plant according to a preferred embodiment of the present invention will be described with reference to the attached FIGS. 1 and 2.

The sprinkler system sprays seawater on the cooling water foam drained from the power plant's drain to physically remove the foam, and automatically controls seawater pumping by detecting the seawater level according to the ebb and flow of the tide.

As shown in FIG. 1, the sprinkler device includes a seawater pump 100, a seawater suction pipe 200, a seawater discharge pipe 300, a sprinkler nozzle 400, and a seawater level detection means 500. .

The seawater pump 100 generates a pumping force to pump seawater through the seawater suction pipe 200 and discharge it to the seawater discharge pipe 300, and is installed on the structure 110 above the seawater. The seawater pump 100 is installed on the base 120 of the structure 110, and the base 120 is preferably treated with epoxy painting.

The seawater suction pipe 200 provides a pipe through which seawater is sucked through the seawater pump 100, and is installed on one side of the seawater pump 100. As shown in FIG. 2, the seawater intake pipe 200 is installed from the structure 110 toward the sea. At this time, the lower part of the seawater intake pipe 200 is installed so that it can be submerged in the sea. It is preferable that the seawater intake pipe 200 is fixed to the side wall of the structure 110 through a fixing bracket 210 or the like to prevent it from flowing due to waves or the like. Meanwhile, it is preferable that a strainer 220 is installed at the lower end of the seawater intake pipe 200. The strainer 220 serves to prevent mechanical failure and damage by filtering out marine life and foreign substances contained in the seawater when seawater is sucked through the seawater suction pipe 200. A check valve 230 is installed between the seawater suction pipe 200 and the seawater pump 100 so that the seawater moves in only one direction. The check valve 230 is preferably a swing check valve including a fan disk.

The seawater discharge pipe 300 provides a pipe for discharging seawater sucked through the seawater pump 100, and is installed on the other side of the seawater pump 100. The seawater discharge pipe 300 is installed from the seawater pump 100 toward the drain side of the power plant. At this time, it is preferable that a check valve 310 is installed between the seawater discharge pipe 300 and the seawater pump 100 so that the seawater discharge direction can be achieved in only one direction. The check valve 310 is also preferably a swing check valve.

The spray nozzle 400 serves to spray seawater discharged from the seawater discharge pipe 300 toward the foam generated in the drain of the power plant, and is installed in the seawater discharge pipe 300 as shown in FIG. 2. The spray nozzle 40 is installed at the end of the seawater discharge pipe 300 so that it can be rotated based on the end.

The seawater level detection means 500 serves to detect the water level of the sea surface being pumped to remove bubbles, and always senses the seawater level and transmits data to the control unit 600. The sea water level detection means 500 detects the water level of the sea surface and detects the stable water level and the lowest sea level based on the height of the sea water intake pipe 200. That is, the sea water level detection means 500 detects the sea level stable water level and the lowest sea level set in the sea water intake pipe 200 and transmits these values to the control unit 600 at any time. At this time, the control unit 600 stops the operation of the seawater pump 100 when the water level of the sea surface is lower than the minimum sea level to temporarily stop the foam removal operation.

Hereinafter, the spraying process of the sprinkler device for removing drainage bubbles in a power plant configured as described above will be described.

Foam appears in the cooling water drained from the power plant, and the manager operates a sprinkler system to remove the drain foam. Afterwards, the seawater pump 100 generates power to raise seawater through the seawater suction pipe 200. Seawater from which foreign substances have been filtered through the strainer (220) is sucked in by opening the check valve (230). It is discharged into the seawater discharge pipe 300. The seawater moved to the seawater discharge pipe 300 is sprayed into the sea where bubbles are formed through the spray nozzle 400. At this time, the spray nozzle 400 can be rotated at the end of the seawater discharge pipe 300, so the spray area for foam removal can be increased. Accordingly, the foam removal efficiency can be increased.

As explained so far, the sprinkler device for removing drainage foam from a power plant according to the present invention pumps seawater and sprays water on the foam formed on the drain side of the power plant, thereby physically removing the foam, but depending on the ebb and flow of the seawater during seawater pumping. The operation of the seawater pump can be controlled automatically. Accordingly, the present invention can prevent sprinkler device failure and damage and increase mechanical life.

Although the present invention has been described in detail with respect to the described embodiments above, it is obvious to those skilled in the art that various changes and modifications are possible within the technical scope of the present invention, and such changes and modifications naturally fall within the scope of the appended patent claims.

100: seawater pump 110: structure
120: Base 200: Seawater suction pipe
210: fixing bracket 220: strainer
230: check valve 300: seawater discharge pipe
310: Check valve 400: Sprinkling nozzle
500: Sea water level detection means 600: Control unit

Claims (3)

A seawater pump installed on a structure above the seawater and capable of generating pumping force;
A seawater suction pipe installed on one side of the seawater pump and providing a conduit through which seawater is sucked by the suction force of the drive pump;
a seawater discharge pipe installed on the other side of the seawater pump and providing a conduit through which seawater is discharged toward the drainage foam;
A spray nozzle installed at the end of the seawater discharge pipe to spray seawater toward the drainage bubbles; and
A sprinkler device for removing drainage foam from a power plant, which is installed in the seawater intake pipe and includes seawater level detection means installed to detect changes in seawater level. According to paragraph 1,
A sprinkler device for removing drainage bubbles in a power plant, characterized in that the sprinkler nozzle is installed to rotate in the seawater discharge pipe. According to claim 1 or 2,
A sprinkler device for removing drainage foam from a power plant, characterized in that a strainer is installed at the lower end of the seawater intake pipe.

Images