KR101240305B1 - Water treatment method and apparatus of ballast tank - Google Patents

Abstract

PURPOSE: A water processing method of a ballast tank and an apparatus using the same are provided to process ballast water within the ballast tank in a reliable and rapid manner at a low price. CONSTITUTION: A water processing method of a ballast tank comprises the following steps: a step of injecting seawater by dropping into a ballast water treatment tank(100) in which carbon dioxide gas is injected at a constant pressure while unloading; a step of deoxidizing the seawater by supplying carbon dioxide gas bubbles into the water, and simultaneously injecting the carbon dioxide gas over the water surface until the concentration of oxygen reaches a predetermined low concentration; and a step of supplying the deoxidized seawater in the ballast water treatment tank to a ballast water storage tank(200) while injecting carbon dioxide over the water surface in the ballast water treatment tank. The method further comprises a step of releasing the seawater in the ballast water storage tank to the sea while loading. In the step of deoxidizing the seawater, the ballast water tank is ventilated when the pressure in the ballast water treatment tank reaches a predetermined pressure.

Description

Water treatment method and apparatus of ballast tank

The present invention relates to a water treatment method and apparatus for a ballast tank.

The vessel shall maintain its stability and regulate the buoyancy by taking water into the ballast tank before departing empty or partially loaded. In fact, in all cases, this ballast water contains living organisms that are influenced by the concentration of dissolved oxygen in the water. When the vessel arrives at its destination and is ready to load the cargo, it discharges this ballast water, so there is a possibility of infiltration to the destination water environment.

It is believed that about 40,000 bulk carriers carry hundreds of billions of tons of ballast water per year to the world and are responsible for introducing hundreds of marine invasive species into the non-vital environment. The total cost of these invasions is undetermined, but many estimates assume billions of dollars.

To address these issues, governments in many countries have passed regulations governing the management of ballast water. The International Maritime Organization has proposed guidelines on the recommended treatment of ballast water. The US Coast Guard is currently setting guidelines for ballast water treatment requirements that are considered for future vessels operating in ports in the United States.

The overwhelming majority of the world's marine groups, including warships and general merchant ships, are constructed of steel. Steel corrodes when exposed to oxygen and water. Corrosion-resistant steel structures of vessels reduce resistance, and a wide range of measures are being taken to avoid or repair them. Estimates of ship's corrosion protection and repair costs amount to billions of dollars annually worldwide.

One area of the vessel where corrosion is particularly concerned is the ballast water tank. For example, the largest oil tankers can have ballast water capacities of up to 15,000,000 gallons (57,000 tons). When the ballast tank structure is exposed to water (in many cases, salt water) for a long period of time, a condition that induces rapid corrosion is formed. The cost of painting ballast tanks is typically $ 5.00 to $ 10.00 per square foot, while in other estimates, the cost of repairing the corrosion zone is about $ 500 per square foot.

Thus, what is needed is a system for treating ballast water in ballast tanks to provide corrosion control in a time and cost effective manner while at the same time excluding aquatic organisms.

One type of excluding aquatic organisms in the ballast water is to inject oxygen stripping gas into the ballast water taken into the ballast tank, as disclosed in Korean Patent Registration No. 10-967910.

The oxygen stripping gas may be nitrogen, carbon dioxide, exhaust gas or a low oxygen gas mixture.

However, there is a problem that it takes a long time to increase the dissolved oxygen of the ballast water by injecting oxygen stripping gas into the water of the ballast tank as a bubble.

The reason is that in the water treatment apparatus disclosed above, the exhaust gas exhausted from the engine of the ship is injected into the water of the ballast tank to increase the hydrogen ion concentration through the reaction between the carbon dioxide contained in the exhaust gas and the ballast tank water, thereby killing the aquatic gas in the ballast tank. In order to increase the hydrogen ion concentration, that is, the pH is 5.0 to inject the compressed air into the ballast water in which the aquatic oil and fat are killed, to exhaust carbon dioxide from the ballast tank, and then to discard the water in the ballast tank where carbon dioxide is exhausted. In order to make the ballast water and the carbon dioxide of the exhaust gas easily to give a large pressure in the ballast water to react easily, because it is inefficient, eventually to increase the hydrogen ion concentration of the ballast water in the ballast tank, to the identification number Hydrochloric acid, such as acetic acid to contaminate the water, as is implicit a problem that the input to the water in the ballast tanks.

In order to solve this problem, a method of deoxygenating the ballast water by supplying the exhaust gas of the ship engine as a fine bubble to the water in the ballast tank using a bubble generator may be proposed.

In addition, in order to rapidly increase the dissolved oxygen in the ballast water, since the shape retention of the bubbles in the ballast water must be large and the surface area in contact with the ballast water must be large, the smaller the microbubbles, the more preferable. There is a problem that there is a limit in reducing bubbles.

The present invention has a problem in solving the above problems.

The present invention, when unloading, A first step in which seawater is injected into the treatment tank in which carbon dioxide gas is injected at a predetermined pressure, and the injected carbon dioxide gas on the sea surface is pressurized to dissolve a portion of the carbon dioxide gas into the injected seawater; Bubbles of carbon dioxide gas are supplied into the water at the same time until a predetermined low oxygen concentration is reached, and carbon dioxide gas is injected into the water, and bubbles of the supplied carbon dioxide gas are dissolved in the water, and Henry's law pushes oxygen out of the water to the surface. When the pressure increases to a certain pressure in the space above the water surface, the treatment tank is vented by a relief valve provided at the upper portion of the water treatment tank, and oxygen in the space above the water surface is released into the atmosphere together with carbon dioxide. A second step of dissolving carbon dioxide gas on the surface of water supplied from the surface of the water and rapidly deoxidizing water in the treatment tank; And injecting carbon dioxide into the treatment tank on the surface of the water, and supplying the deoxidized water of the treatment tank to a ballast water storage tank, and repeating the ballast water of the ballast water storage tank at the time of shipment. By releasing to the sea, the said subject can be solved.

The present invention, in addition to the above configuration, at the time of shipment, A first step in which deoxidized water in the ballast water storage tank is inflowed into the treatment tank into which air is injected at a constant pressure, and the air in the treatment tank is pressurized to dissolve a portion of the air into the ballast water in which the flow of water is injected; By supplying air bubbles to the ballast water in the first stage until the oxygen concentration, such as the oxygen concentration in the sea, and injecting air over the surface of the water, the bubble of air dissolves in the ballast water, and according to Henry's law, When the pressure is pushed onto the water surface and the pressure increases to a certain pressure in the space above the water surface, the processing tank is vented by a relief valve provided at the upper portion of the water tank, and the carbon dioxide gas present in the space above the water is brought into the atmosphere together with air. A second step of dissolving oxygen contained in the air on the surface of the water discharged and continuously supplied from the surface to quickly neutralize the water in the treatment tank; It is more preferable to repeat the cycle including the third step of releasing the neutralized water of the treatment tank into the sea while injecting air into the treatment tank onto the water surface.

According to the problem solving means of the present invention, it becomes possible to treat the ballast water in the ballast tank at low cost, reliably and quickly.

1 is a conceptual diagram showing a water treatment apparatus provided in the ballast water treatment tank of the first embodiment of the present invention, and
Figure 2 is a conceptual diagram showing a water treatment apparatus provided in the ballast water storage tank of the second embodiment of the present invention.

Ballast tank according to the present invention targets the ballast water treatment tank and ballast water storage tank provided in the vessel.

Hereinafter, the water treatment apparatus of the ballast water treatment tank of the first embodiment according to the present invention will be described in detail with reference to FIG.

In Fig. 1, the water treatment apparatus of the ballast water treatment tank of the first embodiment is indicated by reference numeral 1, and the ballast water treatment tank 100 is provided in a vessel not shown, and the treated water is stored in the ballast water. In order to supply to the tank 200, it is connected to the ballast water storage tank 200 in the case of the process water supply pipe 150 in which the pump was interposed.

In addition, in order to transfer the treated water from the ballast water storage tank 200 to the ballast water treatment tank 100, one end of the treated water transfer pipe 160 with the pump interposed therebetween is connected to the lower portion of the ballast water storage tank 200. The other end of the treated water feed pipe 160 is connected in the middle of the seawater supply pipe 10 of the ballast water treatment tank 100.

The water treatment apparatus 1 is provided in a ballast water treatment tank 100 provided in a vessel (not shown).

The water treatment apparatus 1 is connected to the bottom of the ballast water treatment tank 100, the water supply pipe 10 is connected to the upper portion of the ballast water treatment tank 100, the discharge pump is interposed between the water supply pump is ballast water treatment A treatment water discharge pipe 20 for discharging water in the tank 100 to the sea, a first gas supply pipe 30 connected to an upper portion of the ballast water treatment tank 100 at a lower position than the seawater supply pipe 10; A second gas supply pipe 40 connected to the lower portion of the ballast water treatment tank 100 is included.

Carbon dioxide gas supply pipes 31 and 41 and air supply pipes 32 and 42 are connected to each of the first and second gas supply pipes 30 and 40 via valves.

In addition, a porous plate 50 is interposed in the upper portion of the ballast water treatment tank 100 lower than the seawater supply pipe 10 and higher than the first gas supply pipe 30.

In addition, the upper portion of the ballast water treatment tank 100 is opened when the pressure in the ballast water treatment tank 100 is above a predetermined pressure to release the gas in the ballast water treatment tank 100 to the outside and closed when a predetermined pressure or less. For example, a valve 60 such as a relief valve is provided.

In addition, the ballast water treatment tank 100 is provided with an oxygen concentration detection sensor 70 for detecting the oxygen concentration of the ballast water accommodated in the ballast water treatment tank 100 and supplied into the ballast water treatment tank 100. Sea water level detection sensor 90 for detecting the amount is provided.

In addition, downstream of the first and second gas supply pipes 30 and 40, for example, a bubble generator 80 patented by the applicant may be provided.

The water treatment apparatus 1 of the ballast water treatment tank configured as described above may be operated as follows.

First, at unloading, In the case of the seawater supply pipe 10 and the porous plate 50 in the ballast water treatment tank 100 injected with carbon dioxide gas at a constant pressure via the carbon dioxide gas supply pipe 31, the seawater is injected into the water, and the seawater is injected. The carbon dioxide injected into the water surface as the water level of the water in the ballast water treatment tank 100 is increased while dissolving the injected carbon dioxide gas in contact with more carbon dioxide gas, and the water level in the ballast water treatment tank 100 increases. The gas is pressurized by the surface of the water and a part of the carbon dioxide gas is dissolved in the injected seawater.

Next, the bubble of carbon dioxide gas is supplied to the surface of the ballast water treatment tank 100 via the carbon dioxide gas supply pipe 41 and the bubble generator 80 in the seawater until the seawater reaches a predetermined low oxygen concentration, and at the same time, the water surface The carbon dioxide gas is injected via the carbon dioxide gas supply pipe (31), and the bubble of the supplied carbon dioxide gas is dissolved in water, and according to Henry's law, oxygen in the water is pushed onto the surface of the water, thereby When the pressure increases to a certain pressure, the ballast water treatment tank 100 is vented by a relief valve 60 provided on the upper portion of the ballast water treatment tank 100, and oxygen present in the space above the water surface is brought into the atmosphere together with carbon dioxide. The carbon dioxide gas on the surface of the discharged and continuously supplied water is dissolved at the surface of the water, and the ballast water treatment tank 100 The second step is to deoxidize the seawater in) and kill the microorganisms.

Then, while injecting carbon dioxide into the water through the carbon dioxide gas supply pipe 31 to the ballast water treatment tank 100, the deoxidized seawater in the ballast water treatment tank 100 is passed through the ballast water supply pipe 150. A third step of supplying the water storage tank 200 is performed.

In the internal volume, the ballast water storage tank 200 is larger than the ballast water treatment tank 100, so that the dewatered seawater is filled in the ballast water storage tank 200 in the cycle consisting of the first to third steps. Repeat until.

Then, at the time of shipment, the deoxidized seawater of the ballast water storage tank 100 may be discharged to the sea via the treated water discharge pipe 20, but the neutralization treatment does not contaminate the seawater as follows. It is preferable at that point.

In other words, at the time of shipment, The deoxidized seawater in the ballast water storage tank 200 to the ballast water treatment tank 100 into which air is injected at a predetermined pressure is passed through the treated water transport pipe 160, the sea water supply pipe 10, and the porous plate 50. As the water is injected into the fall, the sea water is brought into contact with the injected air to dissolve the oxygen contained in the air while being transported in the ballast water treatment tank 100, and the water level in the ballast water treatment tank 100 is increased. As a result, the air injected above the sea surface is subjected to a first step in which a part of oxygen contained in the air is dissolved in the transferred sea water under pressure by the water surface.

Then, the air is passed through the air supply pipe 42 and the bubble generator 80 in the seawater of the first stage until the seawater in the ballast water treatment tank 100 reaches an oxygen concentration such as the oxygen concentration of the sea. Air is injected into the water via the air supply pipe 32 at the same time as the bubble is supplied, the bubble of the supplied air is dissolved in the water, and according to Henry's law, the carbon dioxide in the water is pushed onto the water surface, thereby When the pressure increases to a predetermined pressure in the above space, the ballast water treatment tank 100 is vented by a relief valve 60 provided on the upper portion of the ballast water treatment tank 100, and air in the space above the water surface Carbon dioxide is released into the atmosphere, oxygen contained in air on the surface of the water continuously supplied is dissolved at the surface, and the seawater in the treatment tank is quickly neutralized. It performs the second step of recovery in sea water.

Then, while the air is injected into the ballast water treatment tank 100 via the air supply pipe 32, the neutralized seawater in the ballast water treatment tank 100 is discharged to the sea via the treated water discharge pipe 20. Perform the third step of releasing.

In the internal volume, the ballast water storage tank 200 is larger than the ballast water treatment tank 100, the sea water deoxidized to the ballast water storage tank 200 empty the cycle consisting of the first to third steps Repeat until you lose.

By the configuration and the water treatment method of the above water treatment apparatus, it becomes possible to treat the ballast water in the ballast tank at low cost, reliably and quickly.

The first embodiment is an example suitable to be applied to an existing vessel.

Hereinafter, the water treatment apparatus of the ballast water storage tank of the second embodiment according to the present invention will be described in detail with reference to FIG.

In Fig. 2, the water treatment apparatus for ballast water storage according to the second embodiment is indicated by the reference numeral 2. The ballast water storage tank 200 is provided with a plurality of airtight vessels, respectively, not shown.

The water treatment apparatus 2 is provided in each of the plurality of ballast water storage tanks 200.

The water treatment device (2) is connected to the bottom of the ballast water storage tank 200, the water supply pipe 10 is connected to the upper portion of the ballast water storage tank 200, the discharge pump is interposed between the water supply pump is stored ballast water storage A treated water discharge pipe 20 for discharging water in the tank 200 to the sea, a first gas supply pipe 30 connected to an upper portion of the ballast water storage tank 200 at a lower position than the seawater supply pipe 10; The second gas supply pipe 40 connected to the lower portion of the ballast water storage tank 200 is included.

Carbon dioxide gas supply pipes 31 and 41 and air supply pipes 32 and 42 are connected to each of the first and second gas supply pipes 30 and 40 via valves.

In addition, the upper plate of the ballast water storage tank 200 lower than the seawater supply pipe 10 and higher than the first gas supply pipe 30 is interposed and fixed with a porous plate 50 interposed therebetween.

In addition, the upper portion of the ballast water storage tank 200 is opened when the pressure in the ballast water storage tank 200 is a predetermined pressure or more to discharge the gas in the ballast water storage tank 200 to the outside and closed when a predetermined pressure or less. For example, a valve 60 such as a relief valve is provided.

In addition, the ballast water storage tank 200 is provided with an oxygen concentration detection sensor 70 for detecting the oxygen concentration of the ballast water contained in the ballast water storage tank 200 and is supplied in the ballast water storage tank 200. Sea water level detection sensor 90 for detecting the amount is provided.

In addition, downstream of the first and second gas supply pipes 30 and 40, for example, a bubble generator 80 patented by the applicant may be provided.

The water treatment device 2 of the ballast water storage tank configured as described above may be operated as follows.

First, at unloading, In the case of the seawater supply pipe 10 and the perforated plate 50 in the ballast water storage tank 200 in which carbon dioxide gas is injected at a predetermined pressure via the carbon dioxide gas supply pipe 31, the seawater is injected into the water while the seawater is injected. The carbon dioxide injected in contact with the carbon dioxide gas is supplied to the ballast water storage tank 200 while dissolving the injected carbon dioxide gas, and the seawater level in the ballast water storage tank 200 increases. The gas is pressurized by the surface of the water and a part of the carbon dioxide gas is dissolved in the injected seawater.

Next, the bubble of carbon dioxide gas is supplied to the surface of the ballast water storage tank 200 through the carbon dioxide gas supply pipe 41 and the bubble generator 80 in the seawater until the seawater reaches a predetermined low oxygen concentration, and at the same time the water surface The carbon dioxide gas is injected via the carbon dioxide gas supply pipe 31 so that the bubble of the supplied carbon dioxide gas is dissolved in the water, and according to Henry's law, the oxygen in the water is pushed up to the surface of the water, thereby When the pressure increases to a certain pressure, the ballast water storage tank 200 is ventilated by a relief valve provided at the upper portion of the ballast water storage tank 200, the oxygen present in the space above the water is released into the atmosphere with carbon dioxide, Carbon dioxide gas on the water surface continuously supplied is dissolved at the surface, and the seawater in the treatment tank is quickly deoxidized. It is carried out a second step that kill microorganisms.

Then, at the time of shipment, the seawater of the ballast water storage tank may be discharged into the sea, but it is preferable in that it does not contaminate the seawater even when neutralized as follows.

In other words, at the time of shipment, Air bubbles are supplied through the air supply pipe 42 and the bubble generator 80 into the water of the seawater until the seawater in the ballast water storage tank 200 reaches an oxygen concentration such as the oxygen concentration of the sea, Air is injected through the air supply pipe 32, and the bubble of the supplied air is dissolved in water, and according to Henry's law, the carbon dioxide in the water is pushed over the surface of the water,

As a result, when the pressure increases to a predetermined pressure in the space on the surface of the water, the ballast water storage tank 200 is ventilated by the relief valve 60 provided on the upper portion of the ballast water storage tank 200, and is present in the space on the surface of the water. The carbon dioxide gas is released into the atmosphere together with air, and oxygen contained in the air on the surface of the water continuously supplied is dissolved at the surface, and the seawater in the treatment tank is quickly neutralized to recover the original seawater. .

Next, a second step of discharging the neutralized seawater in the ballast water storage tank 200 to the sea via the treated water discharge pipe 20 is performed.

Then, a third step of injecting carbon dioxide into the ballast water storage tank 200 via the carbon dioxide gas supply pipe 31 is performed.

The configuration and water treatment method of the water treatment apparatus of the second embodiment as described above also makes it possible to treat the ballast water in the ballast tank reliably and quickly at low cost.

The second embodiment is an example suitable for application to a ship being built.

The second embodiment of the water treatment device 2 is applied to the plurality of ballast water storage tanks 200 which are separately sealed, the seawater supply pipes 10 provided in each ballast water storage tank 200 are not shown. It is connected to the header seawater supply pipe, the treated water discharge pipe 20 is connected to the header treated water discharge pipe (not shown), and the carbon dioxide gas supply pipes 31 and 41 are connected to the header carbon dioxide gas supply pipe (not shown), and the air supply pipe ( 32 and 42 may be connected to a header air supply pipe not shown.

Meanwhile, the water treatment apparatuses 1 and 2 of the first and second embodiments store deoxidized seawater in the ballast water storage tank 200 for equilibrium of ships, thereby preventing corrosion of the ballast water storage tank 200. It is preferable from a viewpoint that it can prevent.

Although the gas for deoxidation of seawater in the water treatment apparatuses 1 and 2 of the first and second embodiments has been described as being a carbon dioxide gas, the present invention is not limited thereto and may be exhaust gas exhausted from a shelf engine. It is preferable from the viewpoint of being able to deoxidize seawater at low cost.

On the other hand, in the water treatment apparatuses 1 and 2 of the first and second embodiments, the carbon dioxide gas supply pipes 31 and 41 are connected to a carbon dioxide gas supply source (not shown), and the air supply pipes 32 and 42 are connected to the air supply source. It is obvious to those skilled in the art.

 10; Seawater supply pipe, 20; Treated water discharge pipe, 30; A first gas supply pipe, 40; A second gas supply pipe, 50; Porous plate, 60; Valve, 70; Oxygen sensor, 80; Bubble generator, 90; Seawater Level Detection Sensor

Claims (20)

In the water treatment apparatus of the ballast tank having a closed ballast water treatment tank and a sealed ballast water storage tank connected to both ends of the treated water supply pipe (150) and the treated water transfer pipe (160) interposed with a pump,
A seawater supply pipe 10 connected to the upper portion of the ballast water treatment tank 100 by interposing a water supply pump,
A treated water discharge pipe 20 which is connected to a lower portion of the ballast water treatment tank 100 with a discharge pump interposed to discharge seawater in the ballast water treatment tank 100 to the sea;
A first gas supply pipe 30 connected to an upper portion of the ballast water treatment tank 100 at a position lower than that of the sea water supply pipe 10;
It includes a second gas supply pipe 40 connected to the lower portion of the ballast water treatment tank 100,
Each of the first and second gas supply pipes 30 and 40 is connected to the carbon dioxide gas supply pipes 31 and 41 and the air supply pipes 32 and 42 via valves.
The valve 60 is opened at an upper portion of the ballast water treatment tank 100 when the pressure in the ballast water treatment tank 100 is greater than or equal to a predetermined pressure to release gas in the ballast water treatment tank 100 to the outside, and closes when the pressure is less than or equal to a predetermined pressure. ),
The ballast water treatment tank 100 is provided with an oxygen concentration detection sensor 70 for detecting the oxygen concentration of the seawater contained in the ballast water treatment tank 100 and detects the amount supplied in the ballast water treatment tank 100. Water treatment device of the ballast tank, characterized in that the seawater level detection sensor 90 is provided for. The method of claim 1,
Downstream of the first and second gas supply pipe (30, 40) the water treatment device of the ballast tank, characterized in that the bubble generator (80) is provided. 3. The method according to claim 1 or 2,
The water treatment device of the ballast tank, characterized in that the porous plate 50 is interposed inside the upper portion of the ballast water treatment tank 100 lower than the sea water supply pipe 10 and higher than the first gas supply pipe 30. At unloading time,
A first step in which seawater is dropped into a ballast water treatment tank into which carbon dioxide gas is injected at a predetermined pressure;
A second step of supplying carbon dioxide gas into the water and injecting carbon dioxide gas into the water until the predetermined low oxygen concentration is reached, so that the sea water is deoxidized; And
And a third step of supplying deoxidized water of the ballast water treatment tank to a ballast water storage tank while injecting carbon dioxide into a ballast water treatment tank on the surface of the water. 5. The method of claim 4,
The method of claim 1, further comprising the step of releasing seawater of the ballast water storage tank into the sea. 5. The method of claim 4,
The water treatment method of the ballast tank, characterized in that the ballast water tank is vented when a predetermined pressure is formed in the ballast water treatment tank in the second step. 5. The method of claim 4,
At shipment, A first step in which deoxidized seawater in the ballast water storage tank is inoculated by falling water to the ballast water treatment tank in which air is injected at a constant pressure;
A second step of neutralizing the seawater in the ballast water treatment tank by supplying air bubbles to the seawater of the first stage and injecting air over the water until the oxygen concentration is equal to the oxygen concentration of the sea; And
And injecting air into the ballast water treatment tank on the surface of the water, discharging the neutralized water of the ballast water treatment tank into the sea. 8. The method of claim 7,
And a ballast water treatment tank is vented when a predetermined pressure is formed in the ballast water treatment tank in the second step of neutralizing the seawater. At shipment, A first step in which deoxidized seawater in the ballast water storage tank is inoculated by falling water to the ballast water treatment tank in which air is injected at a constant pressure;
A second step of neutralizing the seawater in the ballast water treatment tank by supplying air bubbles to the seawater of the first stage and injecting air over the water until the oxygen concentration is equal to the oxygen concentration of the sea; And
And injecting air into the ballast water treatment tank on the surface of the water, discharging the neutralized water of the ballast water treatment tank into the sea. The method of claim 9,
The water treatment method of the ballast tank, characterized in that the ballast water treatment tank is vented when a predetermined pressure is formed in the ballast water treatment tank in the second step. In the water treatment device of a ballast tank having a closed ballast water storage tank,
Sea water supply pipe 10 is connected to the upper portion of the ballast water storage tank 200 is interposed with a water supply pump,
Processed water discharge pipe 20 for discharging the seawater in the ballast water storage tank 200 to the sea by the discharge pump is connected to the lower portion of the ballast water storage tank 200,
A first gas supply pipe 30 connected to an upper portion of the ballast water storage tank 200 at a lower position than the sea water supply pipe 10;
It includes a second gas supply pipe 40 connected to the lower portion of the ballast water storage tank 200,
Each of the first and second gas supply pipes 30 and 40 is connected to the carbon dioxide gas supply pipes 31 and 41 and the air supply pipes 32 and 42 via valves.
The valve 60 is opened at an upper portion of the ballast water storage tank 200 when the pressure in the ballast water storage tank 200 is greater than or equal to a predetermined pressure to release the gas in the ballast water storage tank 200 to the outside, and closes when the pressure is less than or equal to the predetermined pressure. ),
The ballast water storage tank 200 is provided with an oxygen concentration detection sensor 70 for detecting the oxygen concentration of the seawater contained in the ballast water storage tank 200 and detects the amount supplied in the ballast water storage tank 200. Water treatment device of the ballast tank, characterized in that the seawater level detection sensor 90 is provided for. 12. The method of claim 11,
Downstream of the first and second gas supply pipe (30, 40) the water treatment device of the ballast tank, characterized in that the bubble generator (80) is provided. The method of claim 11 or 12,
The water treatment device of the ballast tank, characterized in that the porous plate 50 is interposed inside the upper portion of the ballast water storage tank 200 lower than the sea water supply pipe 10 and higher than the first gas supply pipe 30. At unloading time,
A first step in which seawater is dropped into a ballast water storage tank into which carbon dioxide gas is injected at a predetermined pressure;
And a second step in which a bubble of carbon dioxide gas is supplied into the water and a carbon dioxide gas is injected onto the water until the predetermined low oxygen concentration is reached, so that the seawater is deoxidized. The method of claim 14,
The method of claim 1, further comprising the step of releasing seawater of the ballast water storage tank into the sea. The method of claim 14,
And a ballast water storage tank is vented when a predetermined pressure is formed in the ballast water storage tank in the second step. The method of claim 14,
At shipment, Supplying air bubbles to the seawater in the ballast water storage tank and injecting air over the water until the oxygen concentration is equal to the oxygen concentration of the sea, thereby neutralizing the seawater in the ballast water storage tank;
Discharging the neutralized seawater of the ballast water storage tank into the sea; And
The water treatment method of the ballast tank further comprises a third step of injecting carbon dioxide gas into the ballast water storage tank. 18. The method of claim 17,
When the predetermined pressure is formed in the ballast water storage tank in the first step to be neutralized, the ballast water storage tank is aerated. At shipment, Supplying air bubbles to the seawater in the ballast water storage tank into which the carbon dioxide gas is injected, and injecting air over the water to neutralize the seawater in the ballast water storage tank;
Discharging the neutralized seawater of the ballast water storage tank into the sea; And
And a third step of injecting carbon dioxide gas into the ballast water storage tank. 20. The method of claim 19,
And a ballast water storage tank is vented when a predetermined pressure is formed in the ballast water storage tank in the first step.

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