KR20180046584A - Ballast water treatment system - Google Patents

Abstract

The present invention relates to a ballast water treatment apparatus for a vessel and, more specifically, relates to a ballast water treatment apparatus for a vessel, installing a residual gas discharge pipe, which directly discharges hydrogen gas remaining inside to a gas discharge pipe connected to a blower, in an upper part of an electrolysis tank installed on an inlet pipeline, so as to remove a problem, such as malfunction, life reduction, etc., of the electrolysis tank caused by the hydrogen gas. According to the present invention, the apparatus comprises: a preprocessing filter installed on the inlet pipeline to preprocess inflow seawater; the electrolysis tank connected to a rear end of the preprocessing filter in a series on the inlet pipeline to electrolyze the seawater supplied from the preprocessing filter; a gas separator connected to the rear end of the electrolysis tank in a series on the inlet pipeline to separate the hydrogen gas generated during electrolysis of the seawater from the seawater; the gas discharge pipe connected to an upper part of the gas separator to discharge the hydrogen gas separated by the gas separator to the outside of a vessel; and the remaining gas discharge pipe connected between the upper part of the electrolysis tank and the gas discharge pipe to discharge the hydrogen gas remaining inside the electrolysis tank to the gas discharge pipe.

Description

[0001] Ballast water treatment system [0002]

The present invention relates to a ballast water treatment apparatus for ships, and more particularly, to an electrolytic bath provided on an inflow pipe, a residual gas discharge pipe for directly discharging the hydrogen gas remaining in the inside of the electrolytic bath to a gas discharge pipe connected with a blower, And more particularly, to a ballast water treatment apparatus for marine vessels that eliminates such troubles as failure and shortening of life of an electrolytic bath due to gas.

Generally, a large-sized ship is equipped with a ballast tank for storing a certain amount of seawater for use as equilibrium water for the purpose of balancing the ship and safely navigating in a state where the cargo is not loaded.

However, since the ballast water stored in the ballast water tank is taken from one area of the sea and discharged to the other area, it acts as a medium to move marine and disease-causing bacteria in one area to other areas, thereby destroying marine pollution and ecosystem Which is the main cause of death.

Therefore, in order to solve problems such as marine pollution and destruction of ecosystem, when seawater is taken into a ballast water tank in a marine area, the seawater stored in the ballast water tank is discharged to other marine areas and then sterilized and disinfected. have.

That is, a marine equilibrium water treatment apparatus is installed to sterilize and disinfect seawater taken or discharged. The marine equilibrium water treatment apparatus is characterized in that the seawater flowing along the inflow pipe is introduced into the electrolysis tank to be electrolyzed, sterilized and disinfected, and then introduced into the inflow pipe again through the sea water discharge pipe and the hydrogen gas produced in the electrolysis tank is connected to the blower And exhausted to the outside through a gas discharge pipe.

On the other hand, in the marine ballast water treatment apparatus, the electrolytic bath does not sterilize and disinfect seawater flowing along the inflow pipe but only disinfects and disinfects some of the seawater flowing along the split pipe branched from the inflow pipe. There was still a problem causing local marine pollution and ecosystem destruction.

Thus, a marine ballast water treatment apparatus has been developed in which an electrolytic bath is directly connected to an inflow pipe, and a gas separator is connected directly to the rear end of the electrolytic bath to sterilize and disinfect all the inflow water along the inflow pipe.

However, in the marine ballast water treatment apparatus described above, the hydrogen gas generated by the electrolysis in the electrolytic bath is not discharged together with the seawater along the inflow pipe, but a part thereof remains in the electrolytic bath, And shorten the life span.

That is, since the internal water level of the electrolytic bath is lowered by the residual hydrogen gas, the internal electrode plate of the electrolytic bath is not cooled smoothly by the seawater, so that the electrode plate is damaged by the current and the internal insulation of the electrolytic bath is destroyed.

Therefore, it is necessary to study the structure that can completely eliminate the remaining hydrogen gas inside the electrolytic cell to solve problems such as failure of the electrolytic cell caused by residual hydrogen gas and shortening the service life.

Korean Registered Patent No. 10-1287570, published on July 19, 2013. Korean Registered Patent No. 10-1518677, May 2015.

The present invention has been made in order to solve the above-mentioned problem, and it is an object of the present invention to completely discharge hydrogen gas remaining in the electrolytic bath directly connected to the inflow pipe and to prevent the electrolytic bath from failing due to the hydrogen gas remaining in the electrolytic bath And an object of the present invention is to provide a marine equip- ment water treatment apparatus having a structure capable of preventing shutdown such as shortening of life span.

The objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood from the following description.

According to an aspect of the present invention, there is provided a marine ballast water treatment apparatus comprising: a pretreatment filter installed on an inlet pipe for pretreating seawater flowing into the inlet pipe; An electrolysis tank connected in series to a downstream end of the pre-treatment filter on the inflow pipe to electrolyze seawater flowing out of the pre-treatment filter; A gas separator connected in series to a downstream end of the electrolytic bath on the inflow pipe to separate hydrogen gas generated during electrolysis of the seawater from seawater; A gas discharge pipe connected to an upper part of the gas separator and discharging the hydrogen gas separated from the gas separator to the outside of the ship; And a residual gas discharge pipe connected between an upper portion of the electrolytic cell and the gas discharge pipe to discharge hydrogen gas remaining in the electrolytic bath to the gas discharge pipe.

The electrolytic bath is composed of a plurality of electrolytic baths, and the electrolytic baths are installed in multiple stages with an interval therebetween.

The remaining gas discharge pipe is configured to correspond to the number of the electrolytic baths and has a connection discharge pipe for connecting the upper part of the electrolytic bath which is adjacent to the front and rear sides of the electrolytic bath, and a final discharge pipe for connecting the upper part of the electrolytic bath .

The remaining gas discharge pipe is constituted by an individual discharge pipe constituted corresponding to the number of the electrolytic baths and each having one end connected to the upper part of the electrolytic bath and a collecting discharge pipe connecting the other discharge pipe end and the gas discharge pipe .

Wherein the electrolytic bath is provided with a temperature sensor for sensing an internal temperature of the electrolytic bath in accordance with the remaining hydrogen gas, And an intermittent valve for interrupting the gas discharge pipe is provided.

The present invention provides a ballast water treatment apparatus for marine vessels according to the present invention, in which hydrogen gas remaining in an electrolytic bath is directly discharged to a gas discharge pipe, thereby causing damage to the electrolytic bath caused by hydrogen gas remaining in the electrolytic bath, There is an effect that it is possible to solve at once.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an exemplary view showing a marine ballast water treatment apparatus according to a preferred embodiment of the present invention. FIG.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a ballast water treatment apparatus,

The present invention relates to a method for disinfecting and disinfecting seawater (ballast water) flowing through an inflow pipe and stored in a ballast tank through an electrolysis tank directly connected to an inflow pipe, And to prevent marine pollution and destruction of ecosystem by discharging it.

Particularly, the marine ballast water treatment apparatus according to the present invention completely discharges the hydrogen gas remaining in the electrolytic bath when the seawater is electrolytically split in the electrolytic bath, thereby causing the electrolytic bath to fail, It is characterized by preventing the shorting of the short shaft and the like.

This feature is achieved by a structure in which a residual gas discharge pipe for directly discharging the remaining hydrogen gas to the gas discharge pipe connected to the blower is further provided on the top of the electrolysis tank directly connected to the inlet pipe.

Therefore, since the hydrogen gas generated by the electrolysis is completely discharged from the inside of the electrolytic bath, the level of the internal seawater of the electrolytic bath is kept constant and the electrode plate of the electrolytic bath is cooled by seawater smoothly, And so on.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1, the apparatus for treating marine ballast water 100 according to a preferred embodiment of the present invention includes an inlet pipe 10, a pretreatment filter 20, an electrolytic bath 30, a gas separator 40, a gas A discharge pipe 50 and a residual gas discharge pipe 60.

First, the inflow pipe 10 introduces seawater to be used as ballast water into the ballast water tank. Therefore, the seawater having passed through the inflow pipe 10 is stored in the ballast water tank through the pretreatment filter 20, the electrolytic bath 30, and the gas separator 40 to be described later.

Next, the pretreatment filter 20 is connected in series on the inflow pipe 10, and physically impacts on the marine life included in the seawater introduced through the inflow pipe 10 to kill or weaken it, And to improve the sterilization and disinfection efficiency in the decomposing tank (30).

Next, the electrolytic bath 30 is connected in series to the rear end of the pretreatment filter 20 on the inflow pipe 10, and sterilizes and disinfects all the seawater having passed through the pretreatment filter 20 in an electrolytic manner.

That is, in the electrolytic bath 30, current is applied to a plurality of electrode plates installed therein, and seawater is electrolyzed to generate sodium hypochlorite (NaOCl) used for sterilization and disinfection treatment, To remove the induced bacteria.

At this time, the inner surface of the electrolytic bath 30 is insulated so that a current applied to the electrode plate is not leaked. A plurality of electrolytic baths 30 may be directly connected to the inflow pipe 10 with a gap therebetween in order to increase the efficiency of sterilization and disinfection treatment.

Next, the gas separator 40 is connected in series to the downstream end of the electrolytic bath 30 on the inflow pipe 10 so that the hydrogen gas generated by the electrolysis reaction inside the electrolytic bath 30 is separated into seawater And discharges it to the outside of the ship.

As described above, the seawater from which the hydrogen gas is separated and removed through the gas separator 40 is stored in the ballast water tank along the inflow pipe 10 to function as the ballast water.

Next, the gas discharge pipe (50) is connected to the upper part of the gas separator (40) to discharge hydrogen gas separated from the gas separator (40) to the outside of the ship.

At this time, a blower 51 having a sufficient capacity is provided at the end of the gas discharge pipe 50 so that hydrogen gas can be smoothly discharged to the outside of the ship.

The residual gas discharge pipe 50 is connected between the upper part of the electrolytic bath 30 and the gas discharge pipe 50 so that the hydrogen gas remaining in the electrolytic bath 30 is connected to the flow of the sea water The gas is directly discharged to the gas discharge pipe 50 without being discharged.

Therefore, the hydrogen gas remaining in the electrolytic bath 30 is immediately discharged to the outside of the ship through the residual gas discharge pipe 50 directly connected to the gas discharge pipe 50, so that the electrode plate is damaged due to the residual hydrogen gas, Thereby reducing the performance of the electrolytic bath 30 and shortening the service life thereof.

That is, the hydrogen gas remaining in the electrolytic bath 30 is discharged through the residual gas discharge pipe 50, so that the water level in the electrolytic bath 30 is kept constant, thereby cooling the electrode plate smoothly The damage of the electrode plate due to heat or the breakdown of the internal insulation is naturally prevented.

In this case, although not shown, a temperature sensor for sensing the internal temperature of the electrolytic bath 30 is installed in the electrolytic bath 30, and a residual gas discharge pipe 50 is connected to the electrolytic bath 30 30 may be provided with an intermittent valve that automatically opens and closes the residual gas discharge pipe 50 according to the internal temperature of the gas discharge pipe 30.

Herein, the internal temperature of the electrolytic bath 30 is caused by residual hydrogen gas, meaning that the internal temperature of the electrolytic bath 30 is higher than the reference temperature. This means that the residual hydrogen gas is used as the reference amount (the amount of residual hydrogen gas that causes the electrode plate to become damaged, ), Respectively.

Therefore, when the remaining amount of hydrogen gas becomes equal to or greater than the reference amount in the electrolytic bath 30, the intermittent valve is automatically opened so that the residual hydrogen gas can be discharged through the gas discharge pipe. At this time, the structure including the temperature sensing sensor and the intermittent valve is provided to prevent other phenomena that may occur due to the normal opening of the residual gas discharge pipe 50.

The remaining gas discharge pipe 50 is constituted by a plurality of electrolytic baths 30 and a plurality of electrolytic baths 30 are provided corresponding to the number of the electrolytic baths 30, .

At this time, the remaining gas discharge pipe 50 includes a plurality of connection discharge pipes 61 connecting upper portions of the two electrolytic baths 30 adjacent to each other as shown in FIG. 1, and an electrolytic bath 30 And a final discharge pipe 62 connecting the upper portion and the gas discharge pipe 50.

That is, the hydrogen gas remaining in each electrolytic bath 30 is sequentially moved along the connection discharge pipe 61 and then discharged to the gas discharge pipe 50 through the final discharge pipe 62.

2, the remaining gas discharge pipe 50 includes a plurality of individual discharge pipes 63, one end of which is connected to the upper portion of each electrolytic bath 30, the other discharge pipe 63, 50, which are connected to each other.

That is, the hydrogen gas remaining in each electrolytic bath 30 passes through the individual discharge pipes 63 and then collects in the collecting discharge pipe 64 and is discharged to the gas discharge pipe 50.

The above-described embodiments are merely illustrative, and various modifications may be made by those skilled in the art without departing from the scope of the present invention.

Therefore, the true technical protection scope of the present invention should include not only the above embodiments but also various other modified embodiments according to the technical idea of the invention described in the following claims.

10: Inflow pipe
20: Pretreatment filter
30: electrolysis tank
40: Gas separator
50: gas discharge pipe
51: blower
60: Residual gas discharge pipe
61: connection outlet pipe
62: final discharge pipe
63: Individual discharge pipe
64: Collector discharge pipe

Claims (5)

A pretreatment filter (20) installed on the inflow pipe (10) for pretreating inflowing seawater;
An electrolysis tank (30) connected in series to a downstream end of the pre-treatment filter on the inflow pipe to electrolyze seawater flowing out of the pre-treatment filter;
A gas separator (40) connected in series to a downstream end of the electrolytic bath on the inflow pipe to separate hydrogen gas generated during electrolysis of the seawater from seawater;
A gas discharge pipe (50) connected to the upper part of the gas separator and discharging the hydrogen gas separated from the gas separator to the outside of the ship; And
And a residual gas discharge pipe (60) connected between an upper portion of the electrolytic bath and the gas discharge pipe to discharge hydrogen gas remaining in the electrolytic bath to the gas discharge pipe. The method according to claim 1,
The electrolytic bath
And a plurality of the plurality of water collectors are installed in multiple stages at mutually spaced intervals. 3. The method of claim 2,
The remaining gas discharge pipe
A connection discharge pipe (61) formed of a plurality of electrolytic baths corresponding to the number of the electrolytic baths and connecting the tops of the electrolytic baths adjacent to each other, and a final discharge pipe 62). ≪ / RTI > 3. The method of claim 2,
The remaining gas discharge pipe
An individual discharge pipe (63) constituted by a plurality of the electrolytic baths corresponding to the number of the electrolytic baths, one end of which is connected to the upper part of the electrolytic bath, and an aggregate discharge pipe (64) connecting the other discharge pipe end and the gas discharge pipe Wherein the ballast water treatment apparatus further comprises: The method according to claim 1,
The electrolytic bath
A temperature sensor for detecting an internal temperature of the electrolytic bath according to the remaining hydrogen gas is provided,
The residual gas discharge pipe
And an intermittent valve for interrupting the residual gas discharge pipe according to an internal temperature of the electrolytic bath detected by the temperature sensor.

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