KR20160009380A - Ballast water treatment method - Google Patents

Abstract

A ballast water treatment method is disclosed. The ballast water treatment method according to an embodiment of the present invention includes a transfer pipe to which ballast water is transferred, a ballast water storage tank connected to the transfer pipe to store ballast water, and a rectifier to supply current to the electrode, And a sterilizing material generating unit for supplying a sterilizing material to the transfer pipe through a flow rate control valve, the ballast water processing method comprising the steps of: The method comprising the steps of: injecting a sterilizing material into a pipeline, measuring a concentration of a sterilizing substance in the ballast water flowing into the ballast water storage tank, and comparing the concentration of the sterilizing substance with a reference concentration, Maintaining the current state of the sterilizing material, Increasing the opening of the flow control valve gradually and increasing the current value of the rectifier until the measured sterilant concentration is included in the reference concentration again and if the measured sterilant concentration is higher than the reference concentration, Gradually decreasing the opening of the regulating valve and reducing the current value of the rectifier until the measured germicide concentration again falls within the reference concentration.

Description

[0001] The present invention relates to a ballast water treatment method,

The present invention relates to a method for treating ballast water.

Ballast water is used to control weight distribution in marine vessels. The balance of the ship can be maintained stably during the operation of the ship by ballast water.

It is common for ballast water to be filled at one port and transported elsewhere, where it is discharged to a new port. In this process, marine heterotrophic organisms and bacterial pathogens from other regions are introduced into the affected area, and ecosystems can be rapidly changed or harmful bacterial pathogens can be introduced to cause diseases. To prevent this, the ship is equipped with a ballast water treatment system.

Conventional ballast water treatment devices are designed to sterilize bacterial pathogens by injecting sterilizing materials into the ballast water. A flow meter is generally installed to measure the flow rate of the ballast water and to control the injection amount of the sterilizing material.

However, it is difficult to secure the length of a pipeline constituted by a straight line, unlimitedly, due to the characteristics of a ship having a limited space. As a result, flowmeters are often installed in the piping before and after the flowmeter without securing a recommended level of the straight pipe length, and precise control of the sterilizing material may not be achieved because accurate flow monitoring is not performed.

The precise control of the germicidal material is not realized and the concentration of the germicidal material is out of the operation range, and the ballast water treatment apparatus is shut down and the operation can not be performed.

In addition, when precise control of the germicidal material is not implemented and the concentration of the germicidal material is higher than the reference value, there is a problem in that a large amount of neutralizing agent is unnecessarily consumed in order to neutralize the germicidal substance contained in the ballast water discharged to the outside of the ship And if the concentration of the germicidal material is operated lower than the reference value, viable conditions of the heterotrophic organisms and the bacterial pathogens contained in the ballast water are created so that the heterotrophic organisms and the bacterial pathogens are not sterilized, A problem of regeneration in the tank may occur.

One embodiment of the present invention seeks to provide a method of treating ballast water in which the amount of sterilizing material injected into the ballast water can be precisely controlled.

According to an aspect of the present invention, there is provided a ballast water treatment method comprising: a transfer pipe to which ballast water is transferred; a ballast water storage tank connected to the transfer pipe to store ballast water; a rectifier for supplying current to the electrode, A ballast water treatment method for treating a ballast water using a germicidal material generating unit for generating a germicidal substance and supplying a germicidal substance through the flow control valve to the transfer tube, the method comprising the steps of: Measuring the concentration of the germicidal material in the ballast water flowing into the ballast water storage tank and comparing the concentration of the germicidal material with the reference concentration; if the measured concentration of the germicidal material is the reference concentration, Maintaining the measured concentration of the sterilizing material at a level lower than the reference concentration , Gradually increasing the opening of the flow control valve and increasing the current value of the rectifier until the measured sterilant concentration is included in the reference concentration and if the measured sterilant concentration is higher than the reference concentration, Gradually decreasing the opening of the valve and reducing the current value of the rectifier until the concentration of the germicide again measured is included in the reference concentration.

At this time, if the measured sterilizing material concentration is the reference concentration, the opening of the flow control valve and the current value of the rectifier can be maintained in the initial state in the step of maintaining the injection amount of the sterilizing substance in the current state.

At this time, if the measured concentration of the sterilizing material is lower than the reference concentration, gradually increasing the opening of the flow control valve and increasing the current value of the rectifier until the measured sterilant concentration is included in the reference concentration again, If the measured sterilant concentration is lower than the reference concentration even after gradually increasing the opening of the flow control valve, the current value of the rectifier can be gradually increased.

In the step of gradually decreasing the opening degree of the flow rate control valve and decreasing the current value of the rectifier until the concentration of the sterilizing material is included in the reference concentration again when the measured sterilizing substance concentration is higher than the reference concentration, If the measured sterilant concentration is higher than the reference concentration even after gradually decreasing the opening of the flow control valve, the current value of the rectifier can be gradually reduced.

In the ballast water treatment method according to an embodiment of the present invention, both the flow rate control valve and the rectifier are controlled according to the concentration of the germicidal material measured, so that the concentration of the germicidal material injected into the ballast water can be precisely controlled, The concentration of the substance can be kept constant.

Accordingly, by maintaining the reference concentration of the sterilizing material of the ballast water constantly, it is possible to prevent unnecessary consumption of a large amount of the neutralizing agent to neutralize the sterilizing material contained in the ballast water discharged to the outside of the ship.

In addition, the viability conditions of the heterotrophic organisms and bacterial pathogens included in the ballast water are created to prevent the heterotrophic organisms and bacterial pathogens from being non-sterilized or regenerated.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing a ballast water treatment apparatus to which a ballast water treatment method according to an embodiment of the present invention can be applied. FIG.
2 is a flow chart illustrating a ballast water treatment method according to an embodiment of the present invention;
FIG. 3 is a view showing the flow of ballast water in the process of ballasting in the ballast water treatment apparatus shown in FIG. 1; FIG.
FIG. 4 is a view showing the flow of ballast water in the process of performing de-ballasting in the ballast water treatment apparatus shown in FIG. 1; FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains. The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

Throughout the specification, when a part is referred to as being "connected" to another part, it includes not only "directly connected" but also "indirectly connected" between other parts. Also, when a part is referred to as "including " an element, it does not exclude other elements unless specifically stated otherwise.

Before describing a ballast water treatment method according to an embodiment of the present invention, an example of the structure of a ballast water treatment apparatus to which the ballast water treatment method according to an embodiment of the present invention can be applied will be described.

1 is a block diagram showing a ballast water treatment apparatus 200 to which a ballast water treatment method according to an embodiment of the present invention can be applied.

1, the ballast water treatment apparatus 200 includes a transfer pipe 210, a pump 212, a filter 213, a ballast water storage tank 270, a sterilizing material generating unit 220, (250) and a sterilizing material concentration sensing unit (240, 260).

In the transfer pipe (210), the ballast water introduced from the outside of the ship is transferred. A sea chest 211 may be formed at one end of the transfer pipe 210. The seed chest 211 is a strainer installed with flowing seawater to preferentially filter seafood or relatively large foreign substances contained in seawater.

A pump 212 is formed in the transfer pipe 210 to pump the ballast water.

The filter 213 is formed in the transfer pipe 210 and filters the ballast water pumped by the pump 212. The filter 213 filters microorganisms or foreign substances having relatively small sizes. Since the filter 213 included in the general ballast water treatment apparatus 200 can be used, a detailed description thereof will be omitted.

The ballast water storage tank 270 stores the ballast water introduced from the transfer pipe 210. The ballast water storage tank 270 may be one or more. The ballast water discharged from the ballast water storage tank 270 may be discharged to the outside of the hull through an over board formed on the hull.

The sterilizing material generating unit 220 is connected to the transfer pipe 210 to generate sterilizing material from the ballast water supplied from the transfer pipe 210 and injects the generated sterilizing material into the transfer pipe 210 again. The sterilizing material producing unit 220 injects sterilizing material into the conveying pipe 210 connected to the ballast water storage tank 270 so that the sterilizing material conveyed along the conveying pipe 210 after the point at which the sterilizing material is injected, Thereby allowing the water to be introduced into the water storage tank 270.

The generation of sodium hypochlorite (NaOCl) from seawater used as a germicidal material in this germicidal substance producing unit 220 can be explained by the following formula (1).

[Chemical Formula 1]

In the hypochlorite electrolytic cell, an electrode to which a cathode current and a cathode current are applied is formed. When the ballast water is brought into contact with the electrode and a current generated from the rectifier is applied to the electrode, partial electrolysis of sodium chloride (NaCl) contained in the ballast water occurs.

Sodium chloride (NaCl) is decomposed into sodium ion (Na ⁺ ) and chlorine ion (Cl ^- ). An aqueous solution of sodium chloride (NaCl) reacts at the cathode to produce free chlorine.

Hydroxide ions (OH-) in the water migrate from the anode region and react with Na ⁺ and Cl ₂ near the cathode to form sodium hypochlorite (NaOCl) and hydrogen (H ₂ ).

The resulting sodium hypochlorite is used as a germicidal material to sterilize the ballast water. The sterilizing material is injected into the transfer pipe 210 through the flow control valve 230 connected to the transfer pipe 210 and mixed with the ballast water.

The sterilizing material concentration sensing part (240, 260) measures the concentration of the sterilizing material contained in the ballast water. The sterilizing material concentration sensing units 240 and 260 may be one or more of the sterilizing material concentration sensing units 240 and 260. The sterilizing material concentration sensing units 240 and 260 may be disposed at various positions among the pipelines included in the ballast water treatment apparatus 200 .

For example, the sterilizing material concentration sensing unit 240 formed at the portion of the transfer pipe 210 adjacent to the ballast water storage tank 270 measures the sterilizing material concentration of the ballast water flowing into the ballast water storage tank 270 . The sterilizing material concentration sensing unit 260 formed in the pipe discharging the ballast water to the outside of the hull measures the concentration of the sterilizing material of the discharged ballast water.

The sterilizing material concentration sensing units 240 and 260 may be, for example, Total Residual Oxidant (TRO) sensors. Since the total residual oxidizer measurement sensor may be a TRO sensor included in the general ballast water treatment apparatus 200, detailed description thereof will be omitted.

The neutralization unit 250 is positioned downstream of the ballast water storage tank 270 to neutralize residual chlorine in the ballast water discharged from the ballast water storage tank 270.

Here, the downstream side of the ballast water storage tank 270 may be a specific portion of the pipeline to which the ballast water discharged from the ballast water storage tank 270 is transported to be discharged outside the hull. The neutralization unit 250 may be configured to remove residual chlorine, for example, by reacting chlorine with a sulfur dioxide gas, a solution of sodium hydrogen sulfite, or sodium sulfate.

The neutralizing agent used for neutralizing chlorine in the neutralizing unit 250 may be, for example, bisulfite or sulfite or metabisulfite or thiosulfate.

The ballast water is filled in one port and then released in the next port. Residual chlorine in ballast water tanks that have not been depleted after ballast water treatment may have a detrimental effect on marine ecosystems at new ports where ballast water is discharged.

Residual chlorine, for example, used after sterilization of ballast water, can destroy natural plant and animal groups in the ecosystem. The neutralization unit 250 can consume or neutralize the residual chlorine immediately before discharging the ballast water to prevent the marine environment from being destroyed by the residual chlorine.

Meanwhile, the sterilizing material concentration sensing unit 260 described above is used not only for setting the input amount of the neutralizing agent for neutralizing a large amount of chlorine used for sterilization but also measuring the residual chlorine concentration of the discharged ballast water.

For example, the sterilizing material concentration sensing units 240 and 260 are positioned downstream of the neutralization unit 250, and the sterilizing material concentration sensing units 240 and 260 measure the sterilizing material concentration of the ballast water discharged to the outside of the ship. do. If the concentration of the sterilizing material of the ballast water is more than the allowable level, the amount of the neutralizing agent is increased in the neutralizing unit 250. On the other hand, if the concentration of the germicide is below the allowable level, the amount of the neutralizing agent is reduced in the neutralizing unit 250. That is, the sterilizing material concentration sensing units 240 and 260 calculate the input amount of the neutralizing agent used to lower the concentration of the sterilizing material measured below the allowable level, and then input the neutralizing agent into the discharged ballast water.

Hereinafter, a ballast water treatment method according to an embodiment of the present invention for treating ballast water with a ballast water treatment apparatus having the above-described structure will be described.

2 is a flowchart illustrating a method for treating ballast water according to an embodiment of the present invention.

Referring to FIG. 2, the method (S100) for treating ballast water according to an embodiment of the present invention includes the steps of opening the flow control valve to inject sterilizing material into a pipe through which ballast water flows, (S120), comparing the measured concentration of the germicidal material of the ballast water flowing into the ballast water (S120), comparing the measured concentration of the germicidal material with the reference concentration (S130) If the concentration of the substance is lower than the reference concentration, gradually increasing the opening of the flow control valve and increasing the current value of the rectifier until the measured concentration of the sterilant is included in the reference concentration (S140) If the concentration is higher than the reference concentration, the opening degree of the flow control valve is gradually decreased, and the concentration of the sterilization substance again reaches the reference concentration, A it may include the step (S150) of reducing the current value.

Hereinafter, each step of the ballast water treatment method according to an embodiment of the present invention will be described in detail.

(S110) of opening the flow control valve and injecting sterilizing material into the pipe through which the ballast water is moved.

First, a ballast pump for pumping the ballast water to the germicidal material generating unit is operated (S111). The rectifier included in the sterilizing material generating unit is operated (S112), and a current is supplied to the electrode (S113). Accordingly, the sterilizing material may be generated from the electrode including the anode and the cathode (S114) as described above. The resulting germicide is injected into the transfer tube (S115). The germicidal material is diluted in the ballast water being transported along the transfer tube.

At this time, if the measured sterilizing substance concentration is the reference concentration, in the step of maintaining the injection amount of sterilizing substance in the current state (S130), the opening of the flow regulating valve and the current value of the rectifier are maintained in the initial state. Thereby, the injection amount of the sterilizing substance can be maintained in the current state.

Here, the reference concentration may be a concentration of the germicidal substance such that the germs contained in the ballast water can be sterilized. The reference concentration may be, for example, 0.1 ppm or more. If the concentration of the germicidal substance in the ballast water is about 0.1 ppm or more, the heterotrophic bacteria in the ballast water can be completely killed.

The maximum value of the reference concentration can be changed according to the design, so it is not limited. However, if the reference concentration is excessively high, a large amount of neutralizing agent may be unnecessarily consumed in order to neutralize it, so that it may be desirable to set it to an appropriate value. The maximum of the reference concentration may be, for example, about 0.8 ppm.

Alternatively, if the measured sterilizing substance concentration is lower than the reference concentration, gradually increasing the opening of the flow regulating valve and increasing the current value of the rectifier until the measured sterilizing substance concentration is included in the reference concentration ( S140), the current value of the rectifier can be gradually increased when the measured sterilizing material concentration is lower than the reference concentration even after the opening degree of the flow control valve is gradually increased.

In more detail, after the sterilizing substance concentration sensing unit continuously measures the sterilizing substance concentration, the opening degree of the flow control valve is increased (S141), and then the sterilizing substance concentration and the reference concentration are compared again (S142) . If the concentration of the sterilizing material is still lower than the reference concentration, the current value of the rectifier is increased (S143), so that electrolysis is more actively generated at the electrode, thereby further increasing the amount of the sterilizing material.

Then, when the concentration of the sterilizing material becomes the reference concentration, the current value of the rectifier is not changed, and the opening degree of the flow control valve is maintained in the current state. Then, the step of again comparing the reference concentration and the concentration of the germicidal substance is carried out again.

Alternatively, if the measured sterilizing substance concentration is higher than the reference concentration, gradually decreasing the opening of the flow regulating valve and decreasing the current value of the rectifier until the measured sterilizing substance concentration is included in the reference concentration again (S 150 ), The current value of the rectifier can be gradually reduced if the measured sterilizing material concentration is higher than the reference concentration even after the opening degree of the flow control valve is gradually decreased.

More specifically, after the sterilizing material concentration sensing unit continuously measures the sterilizing substance concentration, the opening degree of the flow control valve is decreased (S151), and then the sterilizing substance concentration and the reference concentration are compared again (S152) . If the concentration of the sterilizing material is still higher than the reference concentration, the current value of the rectifier is decreased (S153) to cause less electrolysis at the electrode, thereby reducing the amount of sterilizing material produced. Then, when the concentration of the sterilizing material becomes the reference concentration, the current value of the rectifier is not changed, and the opening degree of the flow control valve is maintained in the current state. Then, the reference concentration and the concentration of the germicide are again compared with each other.

On the other hand, when the ballast water treatment apparatus is composed of a plurality of conveyance pipes, the number of flow control valves can also be increased in proportion to the number of conveyance pipes. For example, in the case where the ballast water treatment apparatus includes two conveyance pipes, since two flow control valves can be disposed in each conveyance pipe, two flow control valves can be provided.

These flow control valves can be controlled by PID control (proportional integral derivative control). PID control is a kind of feedback control that allows the output of the system to maintain the reference voltage based on the error between the control variable and the reference input. It includes proportional control, proportional-integral control, proportional- Derivative control.

As described above, in the ballast water treatment method according to an embodiment of the present invention, both the flow rate control valve and the rectifier are controlled according to the concentration of the germicidal material, so that the concentration of the germicidal material injected into the ballast water can be precisely controlled The concentration of the sterilizing material of the ballast water can be kept constant.

Accordingly, since the concentration of the germicidal material of the ballast water is kept constant, it is possible to prevent unnecessary consumption of a large amount of the neutralizing agent to neutralize the germicidal material contained in the ballast water discharged to the outside of the hull.

In addition, viable conditions of heterotrophs and bacterial pathogens included in the ballast water are created to prevent heterotrophs and bacterial pathogens from being non-sterilized or regenerated in ballast tanks.

Hereinafter, ballasting and discharging (discharging) are performed in the ballast water treatment apparatus 200 (see FIG. 1) to which the ballast water treatment method S100 according to the embodiment of the present invention can be applied The process is briefly explained.

FIG. 3 is a view showing the flow of ballast water in the process of ballasting in the ballast water treatment apparatus shown in FIG. 1. FIG.

Referring to FIG. 3, seawater used as ballast water flows from the outside of the hull through the sea chest 211. The ballast water introduced from the seed chest 211 is pumped by the pump 212 and is conveyed along the conveying pipe 210 through the filter 213. A part of the ballast water transferred along the transfer pipe 210 is supplied to the germicidal material generating unit 220 by another pump 221 and the remaining ballast water is stored in the ballast water storage tank 270.

At this time, a sterilizing material is generated in the sterilizing material producing unit 220, and the sterilizing material is injected into the transfer tube 210. The concentration of the germicidal material in the ballast water is measured in the sterilizing material concentration sensing unit 240 formed at a position adjacent to the ballast water storage tank 270 in the transfer pipe 210, The amount of the germicidal material can be precisely controlled and injected into the conveyance pipe 210 by the ballast water treatment method.

Meanwhile, the sterilizing material concentration sensing units 240 and 260, the flow control valve 230, and the rectifier may be controlled by the controller C. The control unit C may be one used for overall control of the ballast water treatment apparatus 200, for example.

FIG. 4 is a view showing the flow of ballast water in the process of performing de-ballasting in the ballast water treatment apparatus shown in FIG. 1. FIG.

When the ballast water is discharged from the ballast water storage tank 270, the concentration of the sterilizing material of the ballast water is measured at the sterilizing material concentration sensing unit 240 formed at a position adjacent to the ballast water storage tank 270 at the transfer pipe 210 . The neutralizing agent is injected into the ballast water in the neutralizing part 250 corresponding to the measured concentration of the sterilizing material.

The concentration of the germicidal substance in the ballast water is also measured in the germicidal substance concentration sensing unit 260 formed downstream of the neutralization unit 250. Increase or decrease the amount of neutralizer input depending on whether the measured germicide concentration is at a dischargeable level at sea.

On the other hand, although not shown in the drawings, it is also possible to arrange only one neutralizing part so that the neutralizing agent is injected into two conveying pipes in one neutralizing part.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, And are not used to limit the scope of the present invention described in the scope. Therefore, those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

200: ballast water treatment device 210: transfer pipe
211: Seed chest 212, 221: Pump
213: filter 220: sterilizing material producing unit
230: flow rate control valve 240, 260: sterilizing substance concentration sensing section
250: neutralization unit 270: ballast water storage tank
C:

Claims (4)

A ballast water storage tank connected to the transfer pipe and storing the ballast water, a rectifier for supplying current to the electrode, generating a sterilizing material by the electrode, A ballast water treatment method for treating ballast water using a sterilizing material producing unit that supplies sterilizing material to a tube,
Opening the flow control valve to inject sterilizing material into a pipe through which the ballast water is moved,
Measuring the concentration of the germicide of the ballast water flowing into the ballast water storage tank and comparing the measured concentration with the reference concentration,
If the measured sterilizing substance concentration is a reference concentration, maintaining the injection amount of the sterilizing substance at the current state,
Gradually increasing the opening of the flow control valve and increasing the current value of the rectifier until the measured sterilant concentration is included in the reference concentration, and
Gradually decreasing the opening of the flow control valve and decreasing the current value of the rectifier until the measured sterilizing material concentration is included in the reference concentration again if the measured sterilizing substance concentration is higher than the reference concentration, Processing method. The method according to claim 1,
If the measured sterilizing substance concentration is the reference concentration, in the step of maintaining the injection amount of sterilizing substance in the current state,
Wherein the opening of the flow control valve and the current value of the rectifier are maintained at an initial state. The method according to claim 1,
In the step of gradually increasing the opening degree of the flow rate control valve and increasing the current value of the rectifier until the concentration of the sterilant concentration is included in the reference concentration again when the measured sterilization concentration is lower than the reference concentration,
Wherein the current value of the rectifier is gradually increased when the measured sterilizing material concentration is lower than the reference concentration even after the opening degree of the flow control valve is gradually increased. The method according to claim 1,
In the step of gradually reducing the opening of the flow control valve and decreasing the current value of the rectifier until the measured sterilizing material concentration is included in the reference concentration,
Wherein the current value of the rectifier is gradually decreased when the measured sterilizing material concentration is higher than the reference concentration even after the opening degree of the flow control valve is gradually decreased.

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