KR101070948B1 - Ship's ballast water treatment system using electrolysis of sea water - Google Patents

Abstract

The present invention relates to an apparatus for treating ballast water using seawater electrolysis, wherein an oxidant (eg, sodium hypochlorite (NaOCl)) is generated in seawater through an electrolysis device incorporating an insoluble electrode, and using the oxidant, The present invention provides a ballast water treatment apparatus using seawater electrolysis that kills marine organisms in ballast water and enables effective killing of marine organisms in ballast water even in an area where the temperature of the incoming seawater is low.

The present invention for achieving the above object is an automatic backwash filter installed in the branch flow pipe to remove the solids contained in the incoming sea water; A flow rate control device for controlling the flow rate of the seawater introduced through the branch flow pipe; A seawater temperature control device connected to the flow control device to appropriately control the temperature of the inflowing seawater; An electrolysis device connected to the seawater temperature control device and generating an oxidant to kill marine life; An oxidant concentration measuring device for measuring a concentration of an oxidant generated in the electrolysis device; A power supply for controlling a current amount of the electrolysis device according to the concentration of the oxidant measured by the oxidant concentration measuring device; A temperature control unit connected to the seawater temperature control device to control the temperature of the seawater to be properly maintained; A pressure pump for supplying the oxidant generated in the electrolysis device to the main flow pipe; What is configured to include, as the technical gist.

Ballast Water Treatment System, Sodium Hypochlorite, Vessel Waste Heat Recovery, Electric Heater

Description

Ship's ballast water treatment system using electrolysis of sea water}

The present invention relates to a ballast water treatment apparatus using seawater electrolysis, which is stable in an electrolysis apparatus even in a sea area where the temperature of the incoming seawater is low through an electrolysis apparatus incorporating an insoluble electrode and a heat exchange or electric heater system. An apparatus for producing an oxidant (sodium hypochlorite) to effectively kill marine organisms disrupting marine ecosystems in ballast water tanks.

In general, large cargo ships or passenger ships maintain ball balance by introducing ballast water into a separate tank located at the bottom of the ship in order to safely transport the cargo.

The ballast water, which plays an essential role for the safe operation of the ship, is repeated inflow or outflow depending on the weight change of the loading target. This flows into the ballast water tank at the port where the transport object is unloaded and discharges out of the ship at the port loading the transport object.

In this process, marine species of various species contained in ballast water are transported and discharged into the sea, and there are very serious problems that disturb marine ecosystems such as extinction of indigenous marine organisms in the area and transition of biological populations. It is reported.

This problem can be fundamentally solved by killing and discharging marine life contained in the ballast water before discharging the ballast water from ports in other sea areas.

In 2004, the International Maritime Organization (IMO) established the Ballast Water Management Convention, which established the discharge standard for ballast water in order to prevent marine pollution and the destruction of ecosystems by the discharge of ballast water and sediment. Fastened to.

This is a management step by step considering the size of the ship and the application of existing and new ships, etc., the ballast water for the existing ship should be exchanged on the high seas before arriving at the destination, and since 2009 Mandatory installation of ballast water treatment systems for all ships.

The ballast water treatment technology is being developed in connection with the existing water treatment environmental technology. It can be classified mainly by chemical and physical methods such as ozone, chlorine, other biocide, filtration, UV irradiation, advanced oxidation and electrochemical treatment, but it does not meet the treatment criteria of the management guideline of [Ship Ballast Convention]. In addition, IMOs are excluded from international type approval by IMO when treatment by-products affect humans, vessels and the environment.

Therefore, ballast water treatment technologies should consider seawater conditions such as turbidity, temperature and salinity concentrations to ensure adequate performance that meets the treatment criteria of the management guidelines of the [Ship Ballast Water Management Convention] according to the ship's various routes. .

An object of the present invention for solving the above problems is to produce an oxidizing agent (eg, sodium hypochlorite (NaOCl)) in seawater through an electrolysis device incorporating an insoluble electrode, and to use the oxidizing agent in ballast water The present invention provides a ballast water treatment apparatus using seawater electrolysis that kills marine organisms and effectively kills marine organisms in ballast water even in a region where the temperature of the incoming seawater is low.

The present invention to achieve the object as described above and to perform the problem for eliminating the conventional defects, to produce an oxidizing agent (eg, sodium hypochlorite (NaOCl)) in sea water through an electrolysis device incorporating an insoluble electrode, The present invention provides a ballast water treatment apparatus using seawater electrolysis that kills marine organisms in ballast water by using this oxidant, and effectively kills marine organisms in ballast water even in a region where the temperature of the incoming seawater is low. .

As described above, according to the present invention, a stable efficiency of the electrolysis device for treating ballast water in a sea area at low temperatures by appropriately adjusting the temperature of the incoming seawater using the engine and exhaust gas waste heat or electric heater generated from the vessel. It is possible to maintain the marine life, it is also a very useful invention that solves the problem of excessively designed and installed equipment as conventional by improving the oxidant generating efficiency.

Hereinafter, the configuration and the operation of the embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 is an exemplary view showing a ballast water treatment device equipped with a seawater temperature control apparatus according to an embodiment of the present invention, installed in the branch flow pipe 10 separated from the main flow pipe 20 in the sea water The automatic backwash filter 300 and the branch flow pipe 10 are installed to be connected to the branch flow pipe 10 so as not to affect the electrode reaction in the electrolysis device 600 to be described later by removing the included solids. Flow rate control device 200 is installed so as to adjust the inflow amount of the sea water flowing through the seawater temperature control device 500 is connected to the flow rate control device 200 to properly control the temperature of the incoming sea water, and the An electrolysis device 600 connected to the seawater temperature control device 500 to generate an oxidant for killing marine life, and an oxidant concentration measuring device 610 for measuring the concentration of the oxidant generated in the electrolysis device 600. And a power supply device 620 for controlling the current amount of the electrolysis device 600 according to the concentration of the oxidant measured by the oxidant concentration measuring device 610 so that the concentration of the oxidant can be adjusted, and the seawater. The temperature control unit 100 is connected to the temperature control device 500 to control the temperature control of the sea water properly and to supply the oxidant generated from the electrolysis device 600 to the main flow pipe 20. It is configured to include a pressure pump 700.

The seawater temperature control device 500, by adjusting the temperature of the seawater received by receiving a heat source through the heat medium 400 of the vessel to the temperature directly to improve the electrolysis current efficiency in the electrolysis device 600 The main heat exchanger 510 to adjust.

At this time, the temperature control unit 100 is connected between the main heat exchanger 510 and the electrolysis device 600, the thermometer measuring instrument 110 for measuring the temperature of the sea water, and the sea water measured by the thermometer measuring instrument 110 The temperature controller 120 to control the operation of the main heat exchanger 510 according to the temperature of the sea water so that the temperature of the sea water can be properly adjusted, and is installed to be connected to the main heat exchanger 510 is the heat medium 400 of the vessel It is configured to include a temperature control valve 130 for adjusting the flow rate.

The heat medium 400 includes waste heat generated from an engine, waste heat generated from exhaust gas, waste heat generated from a power supply device 620, and the like.

The seawater temperature control device 500 is such that the generation concentration of the oxidant can be increased by appropriately adjusting the temperature of the incoming seawater to improve the electrolysis current efficiency in the electrolysis device 600.

This is because, when the temperature of the sea water is low, as shown in Figure 4, the current efficiency of the electrolysis in the electrolysis device is very low and the concentration of the oxidant is lowered.

According to the present invention, by installing the seawater temperature control device 500, current efficiency is prevented from being lowered without being restricted by local factors such as seasonal factors or polar regions, thereby improving oxidant generation efficiency in seawater. .

In addition, the oxidizer generation efficiency is improved to solve the problem of excessively designing the installation as in the prior art.

Meanwhile, examples of the oxidizing agent include sodium hypochlorite (NaOCl).

Meanwhile, FIG. 2 is an exemplary view showing a state in which an auxiliary heat exchanger 520 is further installed in the main heat exchanger 510 which is a seawater temperature controller of the present invention, and is provided between the heat medium 400 and the main heat exchanger 510. Heat exchanger 520 is further installed to allow indirect heat exchange. The indirect heat exchange method is a case in which a heat exchanger for a heat medium is added to be applied in a case where it is difficult to transfer the heat medium 400 of a ship, and the auxiliary heat exchanger 520 is installed and the main heat exchanger 510 and the auxiliary heat exchanger 520 are installed. The indirect heat exchange is configured through a cycle circulating using the auxiliary pump 530 by configuring a simple water pipe therebetween.

Meanwhile, the temperature control unit 100 is connected between the main heat exchanger 510 and the electrolysis device 600 to measure the temperature of seawater, and to measure the temperature of seawater. It is installed to be connected to the temperature controller 120 and the auxiliary heat exchanger 520 to control the operation of the main heat exchanger 510 and the auxiliary heat exchanger 520 according to the temperature so that the temperature of the sea water can be properly adjusted. It is configured to include a temperature control valve (130).

3 is an exemplary view showing a ballast water treatment apparatus equipped with a seawater temperature control apparatus according to another embodiment of the present invention,

As shown in the figure, the seawater temperature control apparatus 500 of the present invention may be configured as an electric heater 540 when a separate heat medium cannot be used in a vessel or when it is to be configured as a system independent of the vessel.

On the other hand, the temperature control unit 100 at the time of installation of the electric heater 540 is connected between the electric heater 540 and the electrolysis device 600, the thermometer measuring instrument 110 for measuring the temperature of the sea water, and the thermometer measuring instrument 110 And a temperature controller 120 connected to the electric heater 540 to control the operation of the electric heater 540 according to the temperature of the seawater measured by the thermometer measuring unit 110 so that the temperature of the seawater can be properly adjusted. It is configured by.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

1 is an exemplary view showing a ballast water treatment apparatus equipped with a seawater temperature control apparatus according to an embodiment of the present invention,

2 is an exemplary view showing a state in which an auxiliary heat exchanger is further installed in a main heat exchanger which is a seawater temperature control device of the present invention;

3 is an exemplary view showing a ballast water treatment apparatus equipped with a seawater temperature control apparatus according to another embodiment of the present invention,

Figure 4 is an illustration of the change in electrode reaction efficiency according to the temperature change according to the present invention.

<Description of the symbols for the main parts of the drawings>

(10): branch flow piping (20): main flow piping

100: temperature control unit 110: temperature measuring instrument

120: temperature controller (130) temperature control valve
(200): flow control device (300): automatic backwash filter
(400): heat medium (500): seawater temperature control device

510: main heat exchanger 520: secondary heat exchanger

530: auxiliary pump 540: electric heater

(600): electrolysis device (610): oxidizer concentration measuring device

(620): power supply device 700: pressurized pump

Claims (4)

delete delete An automatic backwash filter installed in the branch flow pipe to remove marine organisms having a larger particle size than the solids and filters included in the incoming seawater; A flow rate control device for controlling the flow rate of the seawater introduced through the branch flow pipe; A seawater temperature control device connected to the flow control device to appropriately control the temperature of the inflowing seawater; An electrolysis device connected to the seawater temperature control device and generating an oxidant to kill marine life; An oxidant concentration measuring device for measuring a concentration of an oxidant generated in the electrolysis device; A power supply for controlling a current amount of the electrolysis device according to the concentration of the oxidant measured by the oxidant concentration measuring device; A temperature control unit connected to the seawater temperature control device to control the temperature of the seawater to be properly maintained; It is connected to the seawater temperature control device to control to maintain the temperature of the seawater properly, and a pressure pump for supplying the oxidant generated in the electrolysis device to the main flow pipe; The seawater temperature control device is a main heat exchanger to adjust the temperature of the seawater received by receiving a heat source through the heat medium, The heat exchanger is installed between the heat exchanger and the main heat exchanger, and receives a heat source through the heat medium, and further comprises an auxiliary heat exchanger, wherein the main heat exchanger and the auxiliary heat exchanger is installed between the water pipe and the auxiliary heat exchanger is installed and circulated By indirect heat exchange, The temperature control unit is connected between the main heat exchanger and the electrolysis device, and a thermometer measuring instrument for measuring the temperature of the seawater, and controlling the operation of the main heat exchanger according to the temperature of the seawater measured by the thermometer measuring instrument to properly adjust the temperature of the seawater. A ballast water treatment apparatus using seawater electrolysis comprising a temperature controller for controlling and a temperature control valve installed to be connected to the main heat exchanger to adjust a flow rate of a heat medium of the vessel. The method of claim 3, wherein The seawater temperature control device is a ballast water treatment device using seawater electrolysis, characterized in that the electric heater.

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