KR20120019302A - Apparatus for treating ballast water and vessel having the apparatus - Google Patents

Abstract

PURPOSE: An apparatus for treating ballast water and vessels including the same are provided to simplify treating processes and to improve the efficiency of the treatment by suffocating bacteria, aquatic animals or vegetable organisms contained in ballast water. CONSTITUTION: An apparatus for treating ballast water(11) includes a reacting part(17), a treating water pipe(35), a hydrogen supplying part(25), and a controlling part(19). The reacting part includes a casing(17a) and a precious metal catalyst(17b). The precious metal catalyst is arranged in the casing. The treating water pipe connects the casing and a ballast water tank(13). The hydrogen supplying part is in connection with the casing through the hydrogen supplying pipe. The hydrogen supplying pipe supplies hydrogen into the casing and converts dissolved seawater oxygen into water. The controlling part controls the operations of valves to control the flow of seawater and hydrogen gas.

Description

Ballast water treatment apparatus and vessel having same {Apparatus for treating ballast water and Vessel having the apparatus}

The present invention relates to a ballast water treatment apparatus and a vessel having the same.

Ballast water is water that is filled in a vessel so that the vessel in operation can have sufficient stability on the water and maintain adequate draft and trim angles. Sufficient resilience and proper draft are essential for safe navigation, so the ballast water must be filled before departure. In addition, the ballast water is discharged at the point of arrival when the vessel arrives at its destination and refilled when the vessel departs. For this purpose, ships are provided with ballast tanks filled with ballast water and intake and drainage facilities.

On the other hand, the ballast water is usually used sea water (sea water) around the ship. However, the seawater contains various bacteria, toxic microorganisms, or flora and fauna that make up the local ecosystem. The above bacteria, toxic algae or animal and plant organisms are filled in the ballast tanks in the seawater and transported to the point of arrival and discharged.

Large vessels such as oil tankers and container ships operate across the ocean, so bacteria and flora and fauna distributed near the US ports, for example, are discharged across Busan to South Korea's Busan port to It can be destroyed. For example, when the above-mentioned toxic microorganism is a pathogen such as cholera bacteria, it may cause damage to animals and humans living on land.

Accordingly, the vessel is required to be provided with a ballast water treatment device for removing pathogenic bacteria, toxic microorganisms or various animal and plant organisms in the ballast water.

As the ballast water treatment system described above, for example, techniques have been proposed, such as ultraviolet irradiation, physical treatment using cavitation, sterilization with hypochlorite, inert gas injection, and decompression of ballast tanks. However, the above technologies have the disadvantage that the power consumption is severe or the processing efficiency is low, in particular, the decompression method of the ballast tank requires a perfect sealing of the ballast tank, the decompression is properly made even if there is a minute gap in the tank due to corrosion, etc. Treatment efficiency is very low.

The present invention has been made to solve the above problems, by reducing the concentration of dissolved oxygen dissolved in the ballast water, has the principle of asphyxiating and killing various pathogenic bacteria or toxic algae or other flora and fauna mixed in the ballast water Therefore, it is an object of the present invention to provide a ballast water treatment apparatus and a vessel having the same, the treatment process is simple and high efficiency.

The ballast water treatment apparatus of the present invention for achieving the above object is installed in a vessel provided with a ballast tank, the dissolved oxygen concentration inside the ballast water supplied to the ballast tank is mixed in the ballast water It kills bacteria and animals and plants, and includes a casing for receiving and passing external seawater through the seawater pipe provided with a valve, and a precious metal catalyst embedded in the casing and in contact with the seawater passing through the casing. A reaction treatment unit; A treated water pipe connecting the casing and the ballast tank to guide the treated water passing through the reaction treatment unit to the ballast tank and to be opened and closed by a valve; It is connected to the casing through a hydrogen pipe provided with a valve, and the hydrogen gas is supplied into the casing so that the hydrogen gas converts dissolved oxygen in the seawater into water through a chemical reaction with a noble metal catalyst in the seawater atmosphere. A hydrogen supply unit for reducing the concentration of oxygen; It characterized in that it comprises a control unit for controlling the flow of sea water and hydrogen gas by controlling the operation of the valve.

The seawater pipe and the treated water pipe are directly connected to each other, and the reaction treatment part is connected to the seawater pipe through the branch pipe and the treated water pipe through the confluence pipe, respectively, and a part of the seawater flowing along the seawater pipe therein. It is characterized in that the treatment, and the treated water is sent to the treated water pipe through the joining pipe.

In addition, the ballast tank and the seawater pipe, characterized in that connected to the circulation pipe having a valve that is opened and closed by the control unit.

In addition, the noble metal catalyst is characterized in that any one of palladium, iridium, osmium, rhodium, ruthenium.

In addition, the hydrogen supply unit; Hydrogen is stored and characterized in that the hydrogen storage tank communicated to the casing of the reaction treatment through the hydrogen pipe.

In addition, the hydrogen supply unit; Hydrogen is generated by electrolyzing water in the interior thereof, and the generated hydrogenerated hydrogen generator supplies the generated hydrogen to the reaction treatment unit through the hydrogen pipe.

In addition, the hydrogen supply unit; Hydrogen is stored and the hydrogen storage tank communicated to the casing of the reaction processing unit through the hydrogen pipe, and the water to generate hydrogen by electrolysis of water therein, the hydrolysis hydrogen generator for supplying the generated hydrogen to the reaction processing unit through the hydrogen pipe Characterized in that composed of.

The ballast tank may further include a sensor for checking the dissolved oxygen concentration in the ballast water supplied to the ballast tank and sending the checked content to the controller, wherein the controller may provide concentration information of the dissolved oxygen. On the basis, it characterized in that for controlling the amount of hydrogen supplied from the hydrogen supply unit to the reaction treatment unit.

The treated water pipe may further include a sensor for checking the dissolved oxygen concentration in the treated water passing through the reaction treatment unit and sending the checked content to the controller, wherein the controller is configured based on the concentration information of the dissolved oxygen. It characterized in that for controlling the amount of hydrogen supplied from the hydrogen supply unit to the reaction treatment unit.

The ship having a ballast water treatment apparatus of the present invention for achieving the above object, the ballast tank that accommodates the ballast water supplied from the outside; A water intake unit for collecting seawater to be supplied to the ballast tank; The casing is connected to the intake section through a seawater pipe provided with a valve, and has a casing for passing the seawater collected by the intake section therein, and a precious metal catalyst provided in the casing and in contact with the seawater passing through the casing. A reaction treatment unit; A treated water pipe connecting the casing and the ballast tank and opening and closing the valve by the valve and connecting the treated water passing through the reaction treatment unit to a ballast tank; It is connected to the casing through a hydrogen pipe provided with a valve, and the hydrogen gas is supplied into the casing so that the hydrogen gas converts dissolved oxygen in the seawater into water through a chemical reaction with a noble metal catalyst in the seawater atmosphere. A hydrogen supply unit for reducing the concentration of oxygen; It characterized in that it has a ballast water treatment apparatus including a control unit for controlling the operation of the valve to adjust the flow rate of sea water and hydrogen gas.

The ballast tank may further include a sensor for checking the dissolved oxygen concentration in the ballast water supplied to the ballast tank and sending the checked content to the controller, wherein the controller may provide concentration information of the dissolved oxygen. On the basis, it characterized in that for controlling the amount of hydrogen supplied from the hydrogen supply unit to the reaction treatment unit.

The treated water pipe may further include a sensor for checking the dissolved oxygen concentration in the treated water passing through the reaction treatment unit and sending the checked content to the controller, wherein the controller is configured based on the concentration information of the dissolved oxygen. It characterized in that for controlling the amount of hydrogen supplied from the hydrogen supply unit to the reaction treatment unit.

The ballast water treatment apparatus and the vessel having the same according to the present invention made as described above may lower the concentration of dissolved oxygen dissolved in the ballast water, and asphyxiate various pathogenic bacteria, toxic algae, and flora and fauna mixed in the ballast water. Because of the principle of killing, the treatment process is simple and high efficiency.

1 is a configuration diagram showing an example of a ballast water treatment apparatus according to an embodiment of the present invention.
Figure 2 is a block diagram showing another example of the ballast water treatment apparatus according to an embodiment of the present invention.
Figure 3 is a block diagram showing another example of the ballast water treatment apparatus according to an embodiment of the present invention.
4 is a view showing another configuration example of the ballast water treatment apparatus according to an embodiment of the present invention.
5 is a view showing another configuration example of the ballast water treatment apparatus according to an embodiment of the present invention.
6 is a view showing another configuration example of the ballast water treatment apparatus according to an embodiment of the present invention.
7 is a schematic view showing a vessel having a ballast water treatment apparatus according to an embodiment of the present invention.

Hereinafter, one embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram showing an example of a ballast water treatment apparatus according to an embodiment of the present invention.

As shown in the drawing, the ballast water treatment apparatus 11 according to the present embodiment includes a reaction treatment unit 17 through which seawater passes and a hydrogen pipe 31 to supply hydrogen to the reaction treatment unit 17. It includes a hydrogen storage tank 15a connected to the reaction treatment unit 17 through. The treated water passing through the reaction treatment unit 17 is supplied to the ballast tank 13 through the treated water pipe 35.

First, the reaction treatment unit 17 includes a casing 17a through which seawater passes and a large amount of metal catalyst 17b installed inside the casing 17a. The size of the casing (17a) or the amount of the metal catalyst (17b) is of course designed differently depending on the number of seawater to be treated.

In any case, the metal catalyst 17b electrochemically reacts with hydrogen supplied from the hydrogen storage tank 15a while submerged in seawater to convert dissolved oxygen in the seawater into water. The electrochemical reaction formula when palladium (Pd) is used as the metal catalyst is as follows.

(1) H ₂ + Pd ^0- > Pd ⁰ + 2H ⁺

^{(2) 2H + + - OO} - -> 2HO-OH

(3) 2H ⁺ + 2HO-OH-> 2H ₂ O

Through the electrochemical reaction described above, 8 g of dissolved oxygen may be removed with 1 g of hydrogen. The reason for removing dissolved oxygen is to choke microorganisms and toxic algae in seawater.

As the metal catalyst 17b, a noble metal is used. For example, palladium, iridium, osmium, rhodium, ruthenium, and the like may be selectively used. Particularly, palladium may be used. As is known, palladium in electrochemistry has a high tendency to ionize and dissolves in an acid to generate hydrogen.

The hydrogen storage tank 15a is connected to the casing 17a through a hydrogen pipe 31 as a space in which high pressure hydrogen is stored. Hydrogen stored in the hydrogen storage tank 15a is introduced into the casing 17a through the hydrogen pipe 31 and reacts with the metal catalyst 17b in the seawater. In addition, a hydrogen storage metal may be applied as a substitute for the hydrogen storage tank 15a.

The hydrogen pipe 31 is provided with a valve 29b and a hydrogen supply unit 25 controlled by the control unit 19. The valve 29b serves to open and close the hydrogen pipe 31 or adjust the flow cross-sectional area, and the hydrogen supply unit 25 serves to supply hydrogen in an appropriate amount. By regulating the valve 29b and the hydrogen supply unit 25 by the control unit 19, it is possible to constantly supply an appropriate amount of hydrogen.

Reference numeral 51 is a water intake part. The intake unit 51 is connected to the reaction treatment unit 17 through the seawater pipe 33 to pull up seawater around the vessel. A filter (not shown) is built in the water intake unit 51. The seawater pipe 33 internally flows the seawater collected by the intake unit 51 and guides the inside of the casing 17a of the reaction treatment unit 17.

The seawater pipe 33 is provided with a filter 23, a valve 29a and a seawater pump 27. The filter 23 removes impurities in the seawater in proximity to the valve 29a. In this way, by installing the filter 23 in the seawater pipe 33, the valve 29a and the seawater pump 27 can be protected.

The valve 29a and the seawater pump 27 are controlled by the control unit 19 described above. The valve 29a opens and closes the seawater pipe 33 or adjusts the flow cross-sectional area. In addition, the seawater pump 27 serves to pump the collected seawater to the reaction treatment unit 17.

In addition, the treated water pipe 35 is piped between the reaction treatment unit 17 and the ballast tank (13). The treated water pipe 35 passes through the reaction treatment unit 17 and guides the treated water, which is treated water, to the ballast tank 13. The valve 29c is also provided in the treated water pipe 35. The valve 29c is a valve opened and closed by the control unit 19.

On the other hand, the sensor 21 is installed in the ballast tank 13 and the treated water pipe 35. The sensor 21 is a sensor for detecting the oxygen concentration in the treated water, the concentration of dissolved oxygen in the treated water stored in the ballast tank 13, or inside the treated water immediately after passing through the reaction treatment unit 17. The concentration of dissolved oxygen is measured and delivered to the controller 19.

The controller 19 adjusts the amount of hydrogen introduced into the reaction processor 17 or adjusts the amount of seawater based on the concentration information received from the sensor 21. The amount of hydrogen supplied or the amount of flow of seawater is adjusted by adjusting the opening and closing amounts of the valves 29a, 29b, and 29c or by controlling the hydrogen supply unit 25 and the seawater pump 27. For example, if the amount of hydrogen is increased, the amount of dissolved oxygen decreases. If the amount of hydrogen is decreased, the amount of dissolved oxygen is relatively increased.

Reference numeral 61 is a bypass line. The bypass line 61 is opened and closed by a valve 61a as a pipe connecting the ballast tank 13 and the seawater pipe 33. The bypass line 61 sends the ballast water to the seawater pipe 33 when the oxygen concentration in the ballast water in the ballast tank 13 is higher than the set value so as to pass the reaction treatment unit 17 again.

Figure 2 is a block diagram showing another example of the ballast water treatment apparatus according to an embodiment of the present invention.

Hereinafter, the same reference numerals as the above reference numerals denote the same members having the same function.

In the case of the ballast water treatment apparatus 11 shown in FIG. 2, a hydrolysis hydrogen generator 15b is applied as a hydrogen supply unit. The hydrolysis hydrogen generator 15b has a positive electrode, a negative electrode, and a power source, and is a general electrolysis device that separates water into hydrogen and oxygen, and is connected to the reaction processor 17 through a hydrogen pipe 31. . Hydrogen generated from the hydrolysis hydrogen generator 15b is supplied to the casing 17a through the valve 29b and the hydrogen supply unit 25 and reacts with the metal catalyst 17b in the casing 17a.

Figure 3 is a block diagram showing another example of the ballast water treatment apparatus according to an embodiment of the present invention.

The ballast water treatment apparatus 11 exemplified in FIG. 3 employs a catalytic hydrogen generator 15c as a hydrogen supply unit. Hydrogen generation formula using the catalyst is

(1) CH ₄ + CO _2- > 2CO + 2H ₂

Nickel, platinum, ruthenium (Ru), rhodium (Rh) can be used as a catalyst used for reaction. Hydrogen generated from the catalytic hydrogen generator 15c is supplied to the reaction treatment unit 17 through the hydrogen pipe 31 and used to reduce dissolved oxygen in seawater.

4 is a view showing another configuration of the ballast water treatment apparatus 11 according to an embodiment of the present invention.

In the ballast water treatment apparatus 11 shown in FIG. 4, the hydrogen supply unit 15a, the hydrolysis hydrogen generator 15b, and the catalytic hydrogen generator 15c are connected in parallel to form a unit ( 15) applies. Hydrogen generated from the hydrogen storage tank 15a, the hydrolysis hydrogen generator 15b, and the catalytic hydrogen generator 15c is supplied to the hydrogen pipe 31 through the valves 29d, 29e, and 29f. In particular, the hydrogen storage tank 15a, the hydrolysis hydrogen generator 15b, and the catalytic hydrogen generator 15c may be selectively or simultaneously operated.

In any case, the hydrogen produced by the hydrogen supply unit 15 moves to the reaction treatment unit 17 through the hydrogen pipe 31 to convert dissolved oxygen into water.

5 is a view showing another configuration example of the ballast water treatment apparatus according to an embodiment of the present invention.

Referring to FIG. 5, it can be seen that the seawater pipe 33 and the ballast tank 13 are connected to the circulation pipe 45. The circulation pipe 45 is a pipe opened and closed by a valve 29m, and is a passage for sending the treated water in the ballast tank 13 back to the reaction treatment unit 17. The reason for sending the treated water back to the reaction treatment unit 17 is because the dissolved oxygen content of the treated water in the ballast tank 13 is high. The dissolved oxygen amount is checked by the sensor 21.

In order to circulate the seawater through the circulation pipe 45, of course, the valve 29a of the seawater pipe 33 must be blocked. That is, when the valve 29a is locked to block the fresh water inflow, the valve 29m of the circulation pipe 45 is opened and the seawater pump 27 is operated to treat the water supplied to the ballast tank 13. Return to the ballast tank 13 through the circulation pipe 45, the sea water pump 27, the reaction treatment unit 17 and the treated water pipe (35).

By circulating the treated water as described above, the treated water is once again processed through the reaction treatment unit 17, and the dissolved oxygen in the treated water is further lean. By repeating this circulation movement, the dissolved oxygen in the ballast tank 13 can be dropped to almost zero level.

6 is a view showing another configuration example of the ballast water treatment apparatus according to an embodiment of the present invention.

As shown in the drawing, the seawater pipe 33 and the treated water pipe 35 are directly connected through the valve 29n. A branch pipe 41 is connected to the seawater pipe 33, and a joining pipe 43 is connected to the treated water pipe 35. In addition, the reaction treatment unit 17 is disposed between the branch pipe 41 and the confluence pipe 43.

Therefore, when the seawater is supplied through the seawater pipe 33 in the state in which the valve 29n is completely closed, the seawater flowing along the seawater pipe 33 flows out into the branch pipe 41 and is processed by the reaction processing unit 17. It flows to the treated water pipe 35 through the confluence pipe 43.

By controlling the opening degree of the valve 29n, however, the flow rate of seawater falling into the branch pipe 41 can be adjusted. That is, a part of the seawater supplied through the seawater pipe 33 may fall into the branch pipe 41 and the rest may directly enter the ballast tank 13 through the valve 29n.

Instead of directing the collected seawater to the entire reaction treatment unit 17, only part of the seawater is moved to the reaction treatment unit 17 for the advanced treatment of the seawater. This is a view that the average dissolved oxygen concentration inside the ballast tank 13 can be adjusted to a predetermined concentration or less by taking only a portion of the seawater and treating the dissolved oxygen in the seawater taken to near zero at high altitude. Is based on. Reference numeral 37 denotes a high processing unit in this sense.

Figure 7 is a schematic diagram showing a vessel 47 having a ballast water treatment apparatus according to an embodiment of the present invention.

Referring to the drawings, it can be seen that the ballast tank 13, which is isolated by the partition wall 55, is located at the lower side of the ship, and the machine room 49 is provided on the ballast tank 13. The machine room 49 is a space in which the ballast water treatment apparatus 11 is installed.

The ballast water treatment apparatus 11 installed in the machine room 49 includes a reaction treatment unit 17, a hydrogen supply unit 15 for supplying hydrogen to the reaction treatment unit 17, and a control unit 19.

The reaction treatment unit 17 is connected to the water intake unit 51 through the seawater pipe 33. The intake unit 51 takes in seawater around the vessel 47 and guides it to the reaction treatment unit 17. In addition, a treatment water pipe 35 and a circulation pipe 45 are connected to the reaction treatment unit 17.

The treated water pipe 35 passes through the reaction treatment unit 17 and is a passage for supplying the treated water to the ballast tank 13. In particular, the treated water pipe 35 is provided with a sensor 21. The sensor 21 checks the dissolved oxygen concentration inside the treated water passing through the treated water pipe 35. The oxygen concentration information detected by the sensor 21 is transmitted to the controller 19 to cause the controller 19 to perform an appropriate control operation.

In addition, the circulation pipe 45 is provided with a pump 53. The pump 53 operates when the dissolved oxygen in the ballast water stored in the ballast tank 13 is higher than the target value, and returns the ballast water to the reaction treatment unit 17. The pump 53 is operated by the control unit 19 received the concentration information of dissolved oxygen from the sensor 21. The pump 53 does not operate if the concentration of dissolved oxygen in the ballast tank 13 is appropriate.

As a result, the vessel 47 having the ballast water treatment device pumps seawater at the bottom of the vessel to the ballast tank 13, but adds hydrogen to the seawater moving to the ballast tank to reduce the dissolved oxygen in the seawater. Do not allow microorganisms, toxic birds or other animal or plant organisms to live inside.

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, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

11: Ballast water treatment unit 13: Ballast tank
15: hydrogen supply unit 15a: hydrogen storage tank
15b: hydrolysis generator 15c: catalytic hydrogen generator
17: reaction treatment unit 17a: casing
17b: metal catalyst 19: control unit
21: sensor 23: filter
25: hydrogen supply unit 27: sea water pump
29a, 29b, 29c, 29d, 29e, 29f, 29m, 29n: Valve
31: hydrogen pipe 33: seawater pipe
35: treated water pipe 37: advanced treatment part
41: branch pipe 43: joining pipe
45: circulation pipe 47: ship
49: machine room 51: water intake
53: pump 55: plate
61: bypass line 61a: valve

Claims (12)

It is installed on a ship provided with a ballast tank, and reduces the dissolved oxygen concentration inside the ballast water supplied to the ballast tank to kill bacteria and animals and plants mixed in the ballast water,
A reaction treatment unit including a casing for receiving and passing external seawater through the seawater pipe provided with a valve, and a noble metal catalyst embedded in the casing and in contact with seawater passing through the casing;
A treated water pipe connecting the casing and the ballast tank to guide the treated water passing through the reaction treatment unit to the ballast tank and to be opened and closed by a valve;
It is connected to the casing through a hydrogen pipe provided with a valve, and the hydrogen gas is supplied into the casing so that the hydrogen gas converts dissolved oxygen in the seawater into water through a chemical reaction with a noble metal catalyst in the seawater atmosphere. A hydrogen supply unit for reducing the concentration of oxygen;
Ballast water treatment apparatus comprising a control unit for controlling the flow of sea water and hydrogen gas by controlling the operation of the valve. The method of claim 1,
The seawater pipe and the treated water pipe are directly connected to each other,
The reaction treatment unit is connected to a seawater pipe through a branch pipe and a treated water pipe through a conduit pipe, respectively, receives and processes a portion of seawater flowing along the seawater pipe, and processes the treated water into a conduit pipe. Ballast water treatment apparatus, characterized in that sent to the treated water pipe through. The method of claim 1,
The ballast tank and the seawater pipe, ballast water treatment apparatus characterized in that connected to the circulation pipe having a valve that is opened and closed by the control unit. The method according to any one of claims 1 to 3,
The noble metal catalyst, ballast water treatment apparatus, characterized in that any one of palladium, iridium, osmium, rhodium, ruthenium. The method according to any one of claims 1 to 3,
The hydrogen supply unit;
The ballast water treatment apparatus of claim 1, wherein hydrogen is stored and is a hydrogen storage tank connected to the casing of the reaction treatment unit through the hydrogen pipe. The method according to any one of claims 1 to 3,
The hydrogen supply unit;
The ballast water treatment apparatus, characterized in that the hydrolysis generator for generating hydrogen by electrolysis of water therein, and supplying the generated hydrogen to the reaction treatment unit through the hydrogen pipe. The method according to any one of claims 1 to 3,
The hydrogen supply unit;
A hydrogen storage tank storing hydrogen and communicating with a casing of the reaction treatment unit through a hydrogen pipe;
The ballast water treatment apparatus of claim 1, wherein the ballast water treatment apparatus comprises a hydrolysis hydrogen generator configured to generate hydrogen by electrolyzing water and supplying the generated hydrogen to the reaction treatment unit through the hydrogen pipe. The method according to any one of claims 1 to 3,
The ballast tank is further provided with a sensor for checking the dissolved oxygen concentration in the ballast water supplied to the ballast tank and sending the checked content to the controller.
The control unit, ballast water treatment apparatus, characterized in that for controlling the amount of hydrogen supplied from the hydrogen supply unit to the reaction treatment unit based on the concentration information of the dissolved oxygen. The method according to any one of claims 1 to 3,
The treated water pipe further includes a sensor for checking the dissolved oxygen concentration in the treated water passing through the reaction treatment unit and sending the checked content to the controller.
The control unit is a ballast water treatment apparatus, characterized in that for controlling the amount of hydrogen supplied from the hydrogen supply to the reaction treatment based on the concentration information of the dissolved oxygen. A ballast tank for receiving ballast water supplied from the outside;
A water intake unit for collecting seawater to be supplied to the ballast tank;
The casing is connected to the intake section through a seawater pipe provided with a valve, and has a casing for passing the seawater collected by the intake section therein, and a precious metal catalyst provided in the casing and in contact with the seawater passing through the casing. A reaction treatment unit;
A treated water pipe connecting the casing and the ballast tank and opening and closing the valve by the valve and connecting the treated water passing through the reaction treatment unit to a ballast tank;
It is connected to the casing through a hydrogen pipe provided with a valve, and the hydrogen gas is supplied into the casing so that the hydrogen gas converts dissolved oxygen in the seawater into water through a chemical reaction with a noble metal catalyst in the seawater atmosphere. A hydrogen supply unit for reducing the concentration of oxygen;
Ship having a ballast water treatment apparatus including a control unit for controlling the operation of the valve to adjust the flow rate of sea water and hydrogen gas. The method of claim 10,
The ballast tank is further provided with a sensor for checking the dissolved oxygen concentration in the ballast water supplied to the ballast tank and sending the checked content to the controller.
The control unit is a vessel having a ballast water treatment apparatus, characterized in that for controlling the amount of hydrogen supplied from the hydrogen supply unit to the reaction treatment unit based on the concentration information of the dissolved oxygen. The method of claim 10,
The treated water pipe further includes a sensor for checking the dissolved oxygen concentration in the treated water passing through the reaction treatment unit and sending the checked content to the controller.
The control unit is a vessel having a ballast water treatment apparatus, characterized in that for controlling the amount of hydrogen supplied from the hydrogen supply unit to the reaction treatment unit based on the concentration information of the dissolved oxygen.

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