KR101472528B1 - Apparatus for treatmenting ballast water using NaDCC - Google Patents

Abstract

The present invention relates to an apparatus for treating ballast water using sodium dichloroisocyanurate that separates and sterilizes part of ballast water flowing through a ballast pipe and injects the treated ballast water into the ballast pipe. The apparatus for treating ballast water using sodium dichloroisocyanurate comprises: a hopper for supplying sodium dichloroisocyanurate; a transfer feeder installed on the hopper to transfer a fixed quantity of sodium dichloroisocyanurate out of the hopper; a primary mixing tank for being provided with sodium dichloroisocyanurate through the transfer feeder by the hopper; a fresh water supplier for supplying a fixed quantity of fresh water to the primary mixing tank; a homogenizer for dissolving sodium dichloroisocyanurate by mixing the sodium dichloroisocyanurate and the fresh water in the primary mixing tank; and a secondary mixing tank receiving the mixture of the sodium dichloroisocyanurate and the fresh water in the primary mixing tank and including a stirrer inside to dissolve additional sodium dichloroisocyanurate and inject the treated water into the ballast pipe.

Description

Technical Field [0001] The present invention relates to an apparatus for treating ballast water using sodium dicarboxylate,

The present invention relates to a ballast water treatment apparatus for sterilizing a ballast water of a ship, and more particularly, to a ballast water treatment apparatus for disinfecting a ballast water, dichloro-isocyanurate).

In general, cargo vessels transported on the sea are mostly single-headed except for vessels that are traveling round-trip for the exchange of similar cargoes. When the ballast water is sailing under full load, ballast water (ballast water) is introduced into the ship for sailing in a ballast condition in order to improve the balance, safety and steering performance of the ship.

At this time, the ballast water is filled in one port and transferred to another, where it is discharged into a new port. As such, the release of marine organisms and pathogens contained in ballast water from a remote location is not only detrimental to the new environment, but can also be dangerous to both humans and animals in new ports.

The introduction of non-natural marine life into new ecosystems can have devastating effects on native flora and fauna that may not have a natural defense system against new species. In addition, harmful bacterial pathogens such as cholera may be present in the original harbor. These pathogens may proliferate in ballast tanks over time and cause disease in areas where they are released.

The risks posed by these marine organisms and pathogens can be controlled by killing the species present in the ballast water.

Here, the method or apparatus for treating the ballast water using the electrolysis method is as follows. The patent application No. 10-2003-0094867 entitled " Electrolytic Ballast Water Treatment Method and Treatment Apparatus Using Sodium Hypochlorite "is a technology for electrolytically treating ballast water of a ballast water tank using sodium hypochlorite, No. 10-2006-0100055 entitled " Ship Ballast Water Sterilization System Using Bipolar Electrolysis System "is a technique that includes an electrolytic sterilization apparatus in a ballast tank and a circulation pump for forcibly circulating it, and Korean Patent Application No. 10 -2005-0103163 is a method for treating ballast water by converting NaCl contained in seawater into NaClO and supplying it to the ballast tank.

However, since the above-described treatment of the ballast water using the electrolysis method is required to convert NaCl contained in the seawater to NaClO, it is easy to use in the seawater region, but in a freshwater region such as a river (in particular, ), There is a disadvantage that the electrolysis method can not be used.

Alternatively, in order to maintain ballast water treatment efficiency in freshwater areas, there is a treatment method in which the ballast water is killed through a chemical injection such as a sterilizing agent in addition to the electrolysis method.

However, in the case of the ballast treatment method using the chemical injection, since the use of two or more chemicals such as sodium hypochlorite (NaClO) and hydrochloric acid is employed, the stability is lowered when applied to ships and the treatment process is somewhat complicated. In addition, the storage time of the drug is shortened due to the short storage period, and the formation efficiency of hypochlorous acid (HOCl) is reduced by forming chlorate or chlorate ion (ClO ₃ -).

Further, in such a chemical injection method, since the fluid flowing in the ballast pipe flows mostly in a laminar flow, it is difficult to completely mix the seawater and the treated water generated with the TRO (oxide) in the treatment water mixing, There is a problem that the hysteresis phenomenon is severe in the TRO measurement due to the incomplete mixing with the number, which makes it difficult to control the system.

Disclosure of the Invention The present invention has been made in order to solve the above-described problems, and it is an object of the present invention to provide a ballast water treatment method capable of sterilizing ballast water even under freshwater conditions, And an object of the present invention is to provide a ballast water treatment apparatus.

According to an aspect of the present invention for accomplishing the above object, there is provided a ballast water treatment method comprising: treating a ballast water flowing through a ballast pipe with a part of the ballast water to sterilize the treated ballast water, and then treating the ballast water with sodium dicarboxylate sodium An apparatus comprising: a hopper to which sodium dicarboxylate is supplied; A feeder provided in the hopper for quantitatively feeding sodium dichloroisocyanurate sodium to the outside of the hopper; A primary mixing tank for receiving sodium hypochloropentasilicate from the hopper through the feeder; A fresh water supply unit for supplying fresh water to the primary mixing tank in a fixed amount; A homogenizer which dissolves sodium dichloroisocyanurate by mixing sodium bicarbonate isocyanurate and fresh water in the primary mixing tank; And a second mixing tank in which a mixture of sodium dichloroisocyanurate and fresh water of the primary mixing tank is transferred and an agitator is provided therein to further dissolve sodium dichloroisocyanurate sodium to inject the treated water into the ballast pipe .

Preferably, a venturi pipe installed between the secondary mixing tank and the ballast pipe, and a dosing pump operable to inject ballast water flowing through the ballast pipe through the venturi pipe and into the ballast pipe, The treated water in the tank-mix tank is diluted with the ballast water and injected into the ballast pipe.

More preferably, the diluted mixture passing through the venturi pipe is mixed through a static mixer or a mixing nozzle when injected into the ballast pipe.

A TRO sensor installed in the ballast pipe injected with the diluted mixture through the venturi pipe to measure the oxidant concentration; And a controller for controlling the operation of the dosing pump based on the measured value of the TRO sensor to maintain the concentration of the sterilizing agent at a constant level.

Preferably, a flow meter and a control valve are provided on the outlet side of the fresh water supplying device and on the outlet side of the secondary mixing tank, respectively, and the control part maintains the concentration of the mixture constant on the basis of the measured values of the TRO sensor and the flow meters And controls the operation of the control valves.

In the meantime, when the sodium hypochlorite is injected into the hopper, the control unit controls the feed feeder, the control valve of the fresh water feeder, and the homogenizer to operate.

Preferably, the apparatus further comprises a dust collector generated by supplying sodium hypochloropentasilicate to the hopper and a cleaning dust collector for purifying and discharging the dust generated in the primary mixing tank and the secondary mixing tank.

More preferably, the dust collecting tank sucks dust generated in the hopper by using a hood and a fan, and a gas generated in the primary mixing tank and the secondary mixing tank flows in. And a circulation pump circulating water in the dust-collecting tank to clean and discharge the dust and gas.

According to the present invention, since the ballast water is sterilized by using only sodium dichloroisocyanuric acid sodium salt, the ballast water treatment can be performed even in the case of fresh water having low salinity, and the process of treating the ballast water is simple and since the powder type medicine is used, It is easy.

In addition, according to the present invention, powdery sodium dichloroisocyanurate sodium is completely dissolved in water through the primary mixing tank and the secondary mixing tank, so that the production efficiency of hypochlorous acid can be increased.

In addition, the present invention can increase the efficiency of the sterilization treatment of the ballast water by completely mixing the treated water and the ballast water and keeping the concentration of the bactericide in the ballast water constant, and by reducing the hysteresis phenomenon in measuring the concentration of the TRO sensor, Is possible.

Further, the present invention can collect and clean sodium dicarboxylate sodium dust and gas, and can safely discharge it to the outside.

Brief Description of Drawings Fig. 1 is a view schematically showing the construction of a ballast water treatment apparatus using sodium dicarboxylate sodium according to the present invention, Fig.
2 is a block diagram schematically showing a control system of a ballast water treatment apparatus using sodium ferricyanosulfuric acid sodium according to the present invention,
3 is a view schematically showing the structure of a dust discharging means of a ballast water treatment apparatus using sodium dicarboxylate sodium isocyanate according to the present invention,

Hereinafter, preferred embodiments of a ballast water treatment apparatus using sodium ferricyanosaccharide sodium according to the present invention will be described with reference to the accompanying drawings. In the following description of the present invention, it is to be understood that the terminology used herein is for the purpose of describing particular embodiments only, and is not intended to be limiting of the technical scope of the present invention. Will be.

FIG. 1 is a view schematically showing the construction of a ballast water treatment apparatus using sodium dichloroisocyanurate sodium according to the present invention, and FIG. 2 is a view showing a control system of a ballast water treatment apparatus using sodium isocyanuric acid dihydrochloride according to the present invention Which is a schematic block diagram.

1 and 2, the ballast water treatment apparatus using sodium dicarboxylate sodium bicarbonate according to the present invention collects and sterilizes some of the ballast water flowing into the ballast tank 20 along the ballast pipe 10 of the ship (HOCL) produced by dissolving sodium dicarboxylate sodium (NaDCC) in water, wherein the ballast water is treated with ballast water Sterilize the water.

In detail, the apparatus for treating ballast water using sodium dicarboxylate sodium bicarbonate according to the present invention comprises a hopper 110, a feeder feeder 120, a primary mixing tank 130, a fresh water feeder 140, a homogenizer 150, And a secondary mixing tank (160).

The hopper 110 receives sodium dicarboxylate sodium in powder form.

The feed feeder 120 is provided at a lower portion of the hopper 110 to feed a predetermined amount of powdered sodium dichloroisocyanurate sodium injected into the hopper 110 to the outside of the hopper 110 and precisely to the primary mixing tank 130 .

The primary mixing tank 130 receives powdered sodium dichloroisocyanurate sodium in a predetermined amount transferred from the hopper 110 through the feeder 120.

The fresh water supply unit 140 supplies fresh water, i.e., water, to the primary mixing tank 130 in a fixed amount. A flow meter 141 and a control valve 142 are installed in the piping connecting the fresh water supply unit 140 and the primary mixing tank 130. On the downstream side of the control valve 142, And a check valve 143 is provided to prevent backflow in the direction of the feeder 140.

The homogenizer 150 is installed at one side of the primary mixing tank 130 to dissolve sodium dichloroisocyanurate in water by mixing powdered sodium dichloroisocyanurate with water. When hypochlorous acid sodium hypochlorite (NaDCC) dissolves in water, hypochlorous acid (HOCL) is generated, and this hypochlorous acid is injected into the ballast pipe 10 to sterilize the ballast water. The homogenizer 150 includes a motor and a stirrer to generate pressure using a general homogenizer or a motor, a crankshaft, and a plunger that stirs the interior of the primary mixing tank 130, And may be a high-pressure homogenizer for homogenizing the interior.

The secondary mixing tank 160 is a tank through which a mixture of fresh sodium bicarbonate and sodium hypochlorite mixed primarily in the primary mixing tank 130 is conveyed and has therein an agitator (not shown) Are further mixed to dissolve sodium dichloroisocyanurate. Thus, powdery sodium dichloroisocyanurate can be mixed in the primary mixing tank 130 and the secondary mixing tank 160 and completely dissolved in water. This makes it possible to increase the production efficiency of hypochlorous acid which is a disinfectant.

A flow meter 161 and a control valve 162 are provided between the secondary mixing tank 160 and the ballast pipe 10. The flow meter 161 and the control valve 162 are installed between the primary mixing tank 130 and the secondary mixing tank 160, The chloric acid is injected into the ballast pipe 10 to sterilize the ballast water.

The ballast water treatment apparatus using sodium isothiocyanate sodium dichloride according to the present invention, which is constructed as described above, treats ballast water using only sodium dicarbonyl isocyanuric acid so that the ballast water treatment can be performed even in the case of fresh water having low salinity, The process is simple, and it is easy to store the medicine by using powdered medicine. In addition, according to the present invention, powdery sodium dichloroisocyanurate sodium is completely dissolved in water through the primary mixing tank and the secondary mixing tank, so that the production efficiency of hypochlorous acid can be increased.

Preferably, the present invention ensures that the mixture containing hypochlorous acid (hereinafter referred to as "treated water") produced through the primary mixing tank 130 and the secondary mixing tank 160 is thoroughly mixed with the ballast water And injecting the treatment water into the ballast pipeline (10) by diluting the treated water at a high concentration.

Specifically, the present invention provides a venturi pipe 170 that is installed between a secondary mixing tank 160 and a ballast pipe 10, and a ballast pipe 170 that operates to supply ballast water flowing through the ballast pipe 10 to the venturi pipe 170 And a pump 180.

The venturi pipe (170) is installed in the bypass pipe (11) bypassed from the upstream side to the downstream side of the ballast pipe (10). The treated water of the secondary mixing tank 160 is injected into the venturi pipe 170 and the ballast water collected from the ballast pipe 10 flows into the entrance of the venturi pipe 170. The treated water and ballast water flowing into the venturi pipe 170 are mixed in the venturi pipe 170 and discharged to the outlet side of the venturi pipe 170. The discharged process water and the ballast water mixture are injected back into the ballast pipe 10 by the operation of the dosing pump 180.

At this time, the venturi pipe 170 is configured to increase the flow passage area from the inlet side to the outlet side, so that the process water and the ballast water flowing into the venturi pipe 170 can be scattered and mixed completely along the traveling direction. Therefore, the high-concentration treated water can be uniformly mixed with the ballast water and diluted.

The apparatus for treating ballast water using sodium isocyanuric acid sodium dichloride according to the present invention is characterized in that when the treated water and ballast water mixed through the venturi pipe 170 are injected into the ballast pipe 10, Such as a static mixer or a mixing nozzle installed in the turbulent flow generating means 190. Therefore, the treated water and the ballast water mixed through the venturi pipe 170 can be completely mixed with the ballast water flowing in the laminar flow from the ballast pipe 10, so that the sterilizing agent (hypochlorous acid) To the ballast tank 20, as shown in FIG.

On the other hand, a check valve 200 for preventing the back flow to the secondary mixing tank 160 through the venturi pipe 170 may be installed in the pipe connecting the venturi pipe 170 and the turbulent flow generating unit 190 have.

Preferably, the apparatus for treating ballast water using sodium dichloroisocyanurate sodium according to the present invention comprises a TRO sensor 210 and a TRO sensor 210 for measuring a concentration of a sterilizing agent (hypochlorous acid) of ballast water injected into the ballast pipe 10 The control unit 220 controls the operation of the dosing pump 180 so as to maintain the concentration of the sterilizing agent in the ballast water uniformly based on the measured value of the ballast water.

The TRO sensor 210 is installed in the inlet side pipe of the ballast tank 20 to measure the concentration of the sterilizing agent in the ballast water flowing into the ballast tank 20. If the measured value is smaller than the set value, the control unit 220 increases the operating load of the dosing pump 180 and controls the flow rate of the treated water flowing into the ballast piping 10 based on the measured value of the bactericide concentration of the TRO sensor 210. [ And when the measured value is larger than the set value, the operating load of the dosing pump 180 is lowered to reduce the amount of the process water flowing into the ballast pipe 10.

Accordingly, the ballast water treatment apparatus using sodium isocyanuric acid dihydrochloride according to the present invention can maintain the concentration of the treated water flowing into the ballast tank 20 constant.

Based on the measured values of the flow meters 141 and 161 and the TRO sensor 210 installed at the outlet side of the fresh water supplying device 140 and the outlet side of the secondary mixing tank 160, Controls the operation of the control valves 142 and 162 so that the concentration of the sterilizing agent in the ballast water flowing into the tank 20 is kept constant.

As described above, according to the present invention, the treatment water and the ballast water are mixed thoroughly and the concentration of the bactericide in the ballast water is kept constant, thereby improving the sterilization treatment efficiency of the ballast water, Control is possible.

Meanwhile, when the sodium hypochlorite is injected into the hopper 110, the controller 220 controls the feed feeder 120, the control valve 142 of the fresh water feeder 140, and the homogenizer 150 to operate in conjunction with each other , The fresh water supply unit 140 and the homogenizer 150 do not require separate operating procedures.

Referring to FIG. 3, the apparatus for treating ballast water using sodium isothiocyanuric acid dihydrochloride according to the present invention comprises: dust generated when sodium hypochlorite is supplied to the hopper 110; And a cleaning dust collector 230 for purifying the gas generated in the tank 160 and discharging the purified gas to the outside.

The cleaning and collecting device 230 sucks the sodium dichromated isocyanuric acid dust generated in the hopper 110 and the sodium dicarboxylate sodium gas generated in the primary mixing tank 130 and the secondary mixing tank 160 is introduced And includes a dust collecting tank 231. The dust generated in the hopper 110 is sucked into the dust collecting tank 231 through the hood 232 and the fan 233 installed on the upper part of the hopper 110. Meanwhile, the gas generated in the primary mixing tank 130 and the secondary mixing tank 160 flows into the dust collecting tank 231 along the pipe by its own pressure without any separate suction means.

The cleaning and dust collector 230 includes a circulation pump 234 circulating water in the dust collection tank 231 to clean and discharge dust and gas.

With this configuration, the washing and collecting dust collector 230 collects and cleans the sodium dicarboxylate dust and gas generated during the above-described process of injecting the sanitizer into the ballast water, and discharges it to the outside (deck 30 of the ship) have.

The embodiments of the present invention described above are merely illustrative of the technical idea of the present invention, and the scope of protection of the present invention should be interpreted according to the claims. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. It should be interpreted that it is included in the scope of right.

10: Ballast piping 20: Ballast tank
30: deck 110: hopper
120: Feed feeder 130: Primary mixing tank
140: fresh water feeder 150: homogenizer
160: Secondary mixing tank 170: Venturi pipe
180: Dosing pump 190: Turbulent flow generating means
141, 161: Flow meters 142, 162: Control valve
143, 200: Check valve 210: TRO sensor
220: control unit 230: cleaning dust collector

Claims (8)

A ballast water treatment apparatus using sodium dicarboxylate sodium which sterilizes and collects a part of ballast water flowing through a ballast pipe, and then injects the treated ballast water into the ballast pipe again,
A hopper fed with sodium dicarboxylate sodium hypochlorite;
A feeder provided in the hopper for quantitatively feeding sodium dichloroisocyanurate sodium to the outside of the hopper;
A primary mixing tank for receiving sodium hypochloropentasilicate from the hopper through the feeder;
A fresh water supply unit for supplying fresh water to the primary mixing tank in a fixed amount;
A homogenizer which dissolves sodium dichloroisocyanurate by mixing sodium bicarbonate isocyanurate and fresh water in the primary mixing tank;
A secondary mixing tank in which a mixture of sodium dichloroisocyanurate and fresh water of the primary mixing tank is transferred and an agitator is provided therein to further dissolve sodium dichloroisocyanurate sodium to inject the treated water into the ballast pipe;
A venturi pipe installed in a bypass pipe bypassed from an upstream side to a downstream side of the ballast pipe and connected to the secondary mixing tank and configured to increase a flow passage area from an inlet side to an outlet side;
The ballast water of the ballast pipe is collected and the collected ballast water is injected into the ballast pipe after passing through the venturi pipe so that the treated water of the secondary mixing tank in the venturi pipe is discharged to the ballast water A dosing pump to dilute the dosing pump;
A TRO sensor installed in the ballast pipe injected with the diluted mixture through the venturi pipe to measure the oxidant concentration; And
And a control unit for controlling the operation of the dosing pump based on the measured value of the TRO sensor to maintain the concentration of the disinfectant at a constant level.
delete The method according to claim 1,
Wherein the diluted mixture passing through the venturi pipe is mixed through a static mixer or a mixing nozzle when injected into a ballast pipe.
delete The method according to claim 1,
A flow meter and a control valve are provided on the outlet side of the fresh water supplying device and the outlet side of the secondary mixing tank respectively and the control part controls the flow rate of the control valve Wherein the operation of the ballast water treatment apparatus is controlled by controlling the operation of the ballast water using sodium dicarboxylate sodium.
The method according to claim 1,
Wherein the control unit causes the feed feeder, the control valve of the fresh water feeder, and the homogenizer to operate in conjunction with each other when the sodium hypochloropentasilicate sodium is injected into the hopper.
The method according to claim 1,
Further comprising a cleaning dust collector for purifying dust generated when sodium hypochlorite is supplied to the hopper and gas generated in the primary mixing tank and the secondary mixing tank to discharge the sodium dichloroisocyanurate sodium. Used ballast water treatment system.
8. The method of claim 7,
The washing /
A dust collecting tank for sucking dust generated from the hopper by using a hood and a fan and for introducing gas generated from the primary mixing tank and the secondary mixing tank; And
And a circulation pump for circulating water in the dust-collecting tank to clean and discharge the dust and gas. [3] The ballast water treatment system according to claim 1,

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