KR101178382B1 - Ballast water sterilization apparatus - Google Patents

Abstract

PURPOSE: A ballast water sterilizing apparatus is provided to separate a sterilizing chamber and a discharging chamber and to position a discharging electrode at the discharging chamber which contains air. CONSTITUTION: A ballast water sterilizing apparatus includes a power supplying part(100), a housing(200), a discharging electrode(300), and a partition(400). The power supplying part generates high voltage pulses. The housing includes a ballast water inlet(210), a ballast water outlet(220), a discharging chamber(700), and a sterilizing chamber(800). The discharging chamber is filled with gas. The sterilizing chamber is formed at the lower side of the discharging chamber in order to store and sterilizer ballast water. The discharging electrode is formed at the upper side of the discharging chamber in the housing in order to discharge high voltage pulses generated from the power supplying part in the discharging chamber. The partition is formed at the center of the housing in order to separate the discharging chamber and the sterilizing chamber.

Description

Ballast Water Sterilizer {BALLAST WATER STERILIZATION APPARATUS}

The present invention relates to a ballast water sterilizer. More specifically, the present invention relates to a ballast water sterilization apparatus which sterilizes ballast water before being stored in a ballast tank of a ship or ballast water before being discharged directly to the ocean from a ballast tank of a ship by using an arc generated from a discharge electrode. .

Ships are widely used for transporting large quantities of goods at once or for military use.

If there are not a lot of people, equipment, and things (called cargo in general) loaded, the ship will not sink enough underwater and can be easily shaken by small waves, and even propellers and rudders will not be submerged enough. It will not work efficiently.

Thus, the ship unloading the cargo is operated in a state containing the ballast water (ballast water: ballast water) in the ballast tank (ballast tank) to maintain the balance and stability. As a result, the ballast water acts as a weight to adjust the draft and trim of the vessel.

On the other hand, a vessel arriving at a port in another region or another country with ballast water in a ballast tank discharges ballast water in the sea at the destination to reduce the weight of the vessel and reload the cargo.

As such, ballast water (ballast water) is essential for the balance and stability of the ship, but on the other hand, ballast water (ballast water) is also stored in the ballast tank for a long time, and also ballast water (ballast water) Can't deny the role of mixing seawater in oceans in different regions, and for this reason several risk factors are of concern.

First, since the ballast water is stored in the ballast tank for a long time, various germs can grow.

Second, it can cause the destruction of ecosystems by mixing foreign marine species of the seas belonging to different regions. For example, organisms or pathogens in a specific seawater contained in ballast water are transported to a different sea area by a vessel containing ballast water, and sprinkled on the oceans of that area, so that organisms of different ecosystems are mixed and In addition to disturbance, there is a risk of causing significant damage to coastal industries and other commercial activities or resources.

Therefore, although various alternatives have been proposed to solve these shortcomings, the efficiency of treatment of ballast water (ballast water) relative to investment cost or facility size is insufficient, so it is not enough to be commercialized. do.

In order to solve this problem, the present invention can effectively solve various problems caused by the use of ballast water (ballast water), as well as improve the sterilization treatment efficiency of ballast water (ballast water) relative to investment cost or facility size. It is an object of the present invention to provide a ballast water sterilizer.

According to the present invention, a power supply for generating a high voltage pulse; A housing including an inflow pipe into which ballast water flows in and an outflow pipe through which the ballast water flows out, including a discharge chamber filled with gas therein and a sterilization chamber formed at a lower end of the discharge chamber to store and sterilize the ballast water; A discharge electrode formed at an upper end of a discharge chamber inside the housing and discharging a high voltage pulse generated by the power supply unit to the discharge chamber; And a partition wall formed at a central portion inside the housing to separate the discharge chamber and the sterilization chamber.

On the other hand, it is formed on the top of the partition wall, the insulating wall which is perforated at a corresponding position of the discharge electrode; characterized in that it further comprises.

On the other hand, the ground electrode is formed in the lower end of the housing in response to the discharge electrode, the ground electrode for inducing the arc discharge generated by the high voltage pulse discharged through the discharge electrode to the gas of the discharge chamber into the sterilization chamber; It characterized in that it further comprises.

On the other hand, the ground electrode is characterized in that it is configured as a plate-like form.

On the other hand, it is formed on top of the ground electrode, characterized in that it further comprises an insulator for insulating between the ballast water in the sterilization chamber of the housing and the ground electrode.

On the other hand, the partition wall is characterized in that the high voltage pulse discharged through the discharge electrode is formed in a metal form so that the arc discharge generated by the gas of the discharge chamber is easily transferred to the ballast water in the sterilization chamber. .

On the other hand, the housing is characterized in that it comprises an insulating material for preventing the arc discharge generated by the high voltage pulse discharged through the discharge electrode reacts with the gas of the discharge chamber to the outside.

Meanwhile, the power supply unit controls the magnitude of the high voltage pulse and the rate of generation of the high voltage pulse for insulation breakdown and recovery of the gas in the discharge chamber according to the shape and size of the discharge chamber and the type of the gas in the discharge chamber. Characterized in that it can.

On the other hand, the discharge electrode is characterized in that configured as a metal rod or metal mash.

On the other hand, the gas is characterized in that it comprises air.

The present invention has the effect of effectively sterilizing small organisms or microorganisms contained in ballast water through arc discharge by high voltage pulses.

In addition, the ballast water sterilization apparatus according to the present invention has a low current dependency and has the effect of safely sterilizing the ballast water by suppressing electrolysis occurring at the electrode while maintaining the electric impact force caused by the strong electric field formed in the water. .

In addition, the present invention by placing the discharge electrode in the discharge chamber containing the air, not the sterilization chamber containing the ballast water can not only prevent the loss due to overcurrent and equipment failure, but also separate the sterilization chamber and the discharge chamber in the ship shaking In the ballast water and the discharge by the high voltage pulse is continuously maintained to further improve the sterilization power.

In addition, the present invention has the effect of improving the sterilization treatment efficiency of the ballast water relative to the investment cost or equipment size.

1 is a block diagram showing a ballast water sterilization apparatus according to an embodiment of the present invention.
FIG. 2 is a view illustrating a state in which an arc is generated by the discharge electrode of FIG. 1 and transferred into the sterilization chamber.
3 is a graph illustrating discharge and dissipation states of high voltage pulses periodically generated by the discharge electrode of FIG. 1.
4 is an actual photograph of an arc generated by the discharge electrode and the ground electrode of FIG. 1.
5a and 5b is a view showing a state before and after the ballast water sterilization by the ballast water sterilization apparatus according to an embodiment of the present invention.
6 is a view showing a state in which the ballast water sterilization apparatus according to an embodiment of the present invention can be actually implemented.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to constituent elements of each drawing, it should be noted that the same constituent elements are denoted by the same reference numerals even though they are shown in different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 is a block diagram showing a ballast water sterilization apparatus according to an embodiment of the present invention, Figure 2 is a view showing a state in which an arc is generated by the discharge electrode of Figure 1 is delivered into the sterilization chamber, Figure 3 FIG. 4 is a graph showing discharge and dissipation states of high voltage pulses periodically generated by the discharge electrode of FIG. 1, and FIG. 4 is an actual picture of the arc generated by the discharge electrode and the ground electrode of FIG. 1, and FIGS. Figure showing the state before and after the ballast water sterilized by the ballast water sterilization apparatus according to an embodiment of the invention, Figure 6 is a view showing a state in which the ballast water sterilization apparatus according to an embodiment of the present invention can be actually implemented to be.

1 and 2, the ballast water sterilizer 10 includes a power supply unit 100, a housing 200, a discharge electrode 300, a partition wall 400, an insulating wall 500, and a ground electrode 600. It includes.

The power supply unit 100 serves to generate a high voltage pulse. The power supply unit 100 is the size and shape of the discharge chamber 700 and the size of the high voltage pulse for insulation breakdown and recovery of the gas in the discharge chamber 700 according to the type of gas in the discharge chamber 700 and The generation rate of the high voltage pulse can be controlled. For example, the power supply unit 100 may generate a high voltage pulse by applying a voltage of 50 ~ 100kV. The application of this voltage breaks the insulation of air among the gases in the discharge chamber 700, and the arc discharge 310 is transmitted to the ballast water A inside the sterilization chamber 800. Referring to FIG. 3, when the high voltage pulse generated by the power supply unit 100 reaches a voltage at which insulation of gas, especially air, inside the discharge chamber 700 is destroyed, that is, an arc discharge start voltage, arc discharge occurs. As a result, the high voltage pulse is periodically periodically repeated to perform insulation breakdown and recovery of gas, especially air, in the discharge chamber 700, thereby inducing arc discharge (see FIG. 4).

The housing 200 includes an inlet pipe 210 through which ballast water A is introduced and an outlet pipe 220 through which the ballast water A flows out, and a discharge chamber 700 filled with gas therein. And a sterilization chamber 800 formed at a lower end of the discharge chamber 700 to store and sterilize the ballast water A. Since the discharge chamber 700 is filled with a gas rather than a ballast water therein, the discharge electrode 300 of the discharge chamber 700 can prevent overcurrent and other accidents caused by the ballast water. In particular, the gas filled in the interior of the discharge chamber 700 may typically include air. The air is a gas having a characteristic of continuously repeating insulation breakdown and insulation recovery by high voltage pulses, and more easily induces arc discharge by high voltage pulses. In addition, the sterilization chamber 800 stores the ballast water therein, the stored ballast water is a small organism and microorganisms in the ballast water by the arc discharge 310 generated by the discharge electrode 300 and the discharge chamber 700 It can be killed.

The housing 200 may include an insulating material that prevents arc discharge generated by the high voltage pulse discharged through the discharge electrode 300 from reacting with the gas in the discharge chamber 700 to the outside. It is preferable that it consists of. Because the housing 200 is made of an insulating material, it is possible to prevent defects and failures of electrical devices in the ship through accidental arc discharge.

The discharge electrode 300 is formed at the upper end of the discharge chamber 700 inside the housing 200, and serves to discharge the high voltage pulse generated by the power supply unit 100 to the discharge chamber 700. The high voltage pulse generated by the power supply unit 100 is transferred into the discharge chamber 700 through the discharge electrode 300, and the transferred high voltage pulse reacts with a gas, especially air, inside the discharge chamber 700 to generate an arc. Discharge occurs. In this case, the high voltage pulse takes the form of a low frequency pulse, and the insulation of the gas (especially air) inside the discharge chamber 700 is destroyed at the same time as the high voltage pulse satisfies the arc discharge starting charge amount, thereby causing arc discharge. The discharge passage is formed for the discharge passage, and the discharge passage is also in a situation of rapidly lowering the impedance and at the same time, the discharge is stopped to recover the insulation of the gas, and the continuous discharge is performed in such a manner that the insulation breakdown and the insulation recovery of the gas are repeated indefinitely. By doing this, it has a repetitive characteristic similar to the oscillation. Therefore, it is possible to control the speed of the high voltage pulse at an applied voltage of a level properly controlled by the power supply unit 100.

The discharge electrode 300 is preferably configured as a metal rod or metal mash. Because the discharge electrode 300 is composed of a metal rod or a metal mesh, the arc discharge 310 can be easily induced by the reaction between the high voltage pulse and the gas inside the discharge chamber 700.

The partition wall 400 is formed at a central portion inside the housing 200 to separate the discharge chamber 700 and the sterilization chamber 800. The partition wall 400 is an arc discharge generated by the high voltage pulse discharged through the discharge electrode 300 and the gas of the discharge chamber 700 is easy to the ballast water (A) in the sterilization chamber (800) It is preferable to be configured in the form of a metal to be delivered easily. Because, by forming the partition 400 separating the discharge chamber 700 and the sterilization chamber 800 in a metal form, the arc discharge generated in the discharge chamber 700 using the properties as a conductor inside the sterilization chamber 800. In order to be better transmitted to the ballast water present in the ballast water it is possible to deliver a strong electric shock wave to the small organisms and microorganisms in the ballast water to kill. In addition, the partition 400 separates the discharge chamber 700 and the sterilization chamber 800 and at the same time serves to prevent the ballast water in the sterilization chamber 800 from flowing into the discharge chamber 700. Accordingly, the partition wall 400 prevents a unidirectional discharge by the discharge electrode 300 of the discharge chamber 700 by preventing fluctuations in the water level of the ballast water in the sterilization chamber 800 due to the shaking of the hull or discharge electrode 300. Submerged in this ballast water, it is possible to prevent overcurrent and accidents that may occur. In addition, the partition wall 400 may be waterproofed so that the ballast water does not flow into the discharge chamber 700, and the partition wall 400 is directly connected to the ballast water of the sterilization chamber 800 to increase sterilization power. .

The insulating wall 500 is formed on an upper end of the partition 400, and is formed in a form in which a perforation is formed at a corresponding position of the discharge electrode 300. Therefore, the insulating wall 500 is spaced apart from the partition 400 by a predetermined distance, and is formed in a form in which a hole is formed in a portion corresponding to the corresponding position of the discharge electrode 300. The insulating wall 500 which is perforated at the corresponding position of the discharge electrode 700 is sterilized by the sterilization chamber 800 through the perforation and partition 400 in the state where the arc discharge generated in the discharge chamber 700 is not dispersed. ) By intensively delivering to the ballast water inside, it is possible to maximize the electric impact force.

The ground electrode 600 is formed at an inner lower end of the housing 200 in response to the discharge electrode 300, and the high voltage pulse discharged through the discharge electrode 300 reacts with the gas in the discharge chamber 700. It is for inducing the arc discharge generated by the inside of the sterilization chamber (800).

The ground electrode 600 is preferably configured in the form of a plate. Accordingly, the ground electrode 600 may serve as a reference electrode (ground electrode) in a stable manner at the inner lower end of the housing 200.

An insulator 610 may be formed on the ground electrode 600 to induce insulation between the ballast water A in the sterilization chamber 800 of the housing 200 and the ground electrode 600. . Therefore, the ground electrode 600 is insulated from the ballast water by the insulator 610, and the ground electrode 600 serves to generate a discharge passage of the arc discharge.

5A and 5B, although the cell membranes of small organisms and microorganisms in the ballast water are still alive before sterilizing the ballast water through the ballast water sterilizing apparatus 10 according to the present invention (FIG. 5A). After sterilizing the ballast water through the ballast water sterilization apparatus 10 (FIG. 5b), it can be confirmed that the cell membranes of small organisms and microorganisms are destroyed and destroyed by arc discharge by high voltage pulses. Therefore, by sterilizing the ballast water through the ballast water sterilization apparatus 10 according to the present invention it is possible to solve the problem in the ballast water use of the vessel. In particular, the ballast water sterilization apparatus 10 according to the present invention, as can be seen in Figure 6, if you want to use in actual vessels arranged in series or in parallel to inlet and out of the ballast water at the same time to sterilize a large amount of ballast water Can be.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Therefore, the embodiments disclosed in the present specification are intended to illustrate rather than limit the present invention, and the scope and spirit of the present invention are not limited by these embodiments. The scope of the present invention should be construed according to the following claims, and all the techniques within the scope of the present invention should be construed as being included in the scope of the present invention.

10: ballast water sterilizer
100: power supply
200: housing
210: inlet pipe
220: outlet pipe
300: discharge electrode
310: arc discharge
400: bulkhead
500: insulation wall
600: ground electrode
610: insulator
700: discharge chamber
800: sterilization chamber
A: Ballast Water

Claims (10)

A power supply for generating a high voltage pulse;
A housing including an inflow pipe into which ballast water flows in and an outflow pipe through which the ballast water flows out, including a discharge chamber filled with gas therein and a sterilization chamber formed at a lower end of the discharge chamber to store and sterilize the ballast water;
A discharge electrode formed at an upper end of a discharge chamber inside the housing and discharging a high voltage pulse generated by the power supply unit to the discharge chamber; And
And a partition wall formed at a central portion inside the housing to separate the discharge chamber and the sterilization chamber.
The method of claim 1,
And an insulating wall formed on an upper end of the partition wall, the insulating wall being perforated at a corresponding position of the discharge electrode.
The method of claim 2,
A ground electrode formed in the lower end portion of the housing in correspondence with the discharge electrode, the ground electrode configured to induce arc discharge generated by the high voltage pulse discharged through the discharge electrode to the gas of the discharge chamber into the sterilization chamber; Ballast water sterilization apparatus comprising a.
The method of claim 3, wherein
Ballast water sterilizing apparatus, characterized in that the ground electrode is configured in the form of a plate.
The method of claim 4, wherein
And an insulator formed on an upper end of the ground electrode and insulated between the ballast water in the sterilization chamber of the housing and the ground electrode.
The method of claim 1,
The partition wall has a ballast water, characterized in that the high voltage pulse discharged through the discharge electrode is formed in a metal form so that the arc discharge generated by the gas of the discharge chamber is easily transferred to the ballast water in the sterilization chamber. Sterilizer.
The method of claim 1,
The housing is ballast water sterilization apparatus comprising an insulating material for preventing the arc discharge generated by the high voltage pulse discharged through the discharge electrode reacts with the gas of the discharge chamber to the outside.
The method of claim 1,
The power supply unit may control the magnitude of the high voltage pulse for insulating breakdown and recovery of the gas in the discharge chamber and the generation speed of the high voltage pulse according to the shape and size of the discharge chamber and the type of the gas in the discharge chamber. Ballast water sterilizer, characterized in that.
The method of claim 1,
Ballast water sterilization apparatus, characterized in that the discharge electrode is configured as a metal rod or a metal mash.
10. The method according to any one of claims 1 to 9,
Ballast water sterilization apparatus, characterized in that the gas comprises air.

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