KR101129620B1 - anti-fouling system and control method thereof - Google Patents

Abstract

An antifouling system using ballast water is disclosed.

The antifouling system according to the present invention is provided with a ballast tank for storing ballast water (ballast water), a ballast water treatment apparatus for generating a sterilizing material for sterilizing marine life contained in the ballast water introduced into the ballast tank; The cost of constructing an antifouling system can be reduced by including an injector for injecting the ballast number discharged from the ballast tank on the surface of the ship's hull.

Ballast water, antifouling system, sprayer, nozzle

Description

Anti-fouling system and control method

The present invention relates to an antifouling system for preventing marine organisms from being attached to the hull of a ship, and more particularly, to an antifouling system using seawater (hereinafter referred to as 'ballast water') stored in a ballast tank, and a method thereof. It relates to a control method.

As the ship sails, various marine life such as barnacles, sea urchins and mussels are attached to the hull of the ship.

When the marine life is attached to the hull the weight of the vessel is increased to reduce the amount of cargo that can be loaded on the vessel.

Marine life attached to the hull also acts as a resistance when the ship is sailing, which not only reduces the speed of the ship, increases the fuel consumption of the ship, but also makes it difficult to maneuver, thereby reducing the ship's performance and efficiency.

As such, anti-fouling systems have emerged to prevent marine life from adhering to the hull surface.

Korean Patent Publication No. 10-2008-0087091 discloses that marine organisms adhere to the hull surface by installing a sodium hypochlorite generator on board and discharging sodium hypochlorite (NaOCl) generated by the sodium hypochlorite generator in the ocean. An example of an antifouling system for preventing is disclosed.

The antifouling system should be separately installed and controlled on board the sodium hypochlorite generator. It should also have a separate storage container for storing sodium hypochlorite produced in the sodium hypochlorite generator.

Therefore, in order to construct the antifouling system, a separate apparatus such as a sodium hypochlorite generator and a storage container must be provided. Therefore, it is expensive to construct the antifouling system.

In addition, the antifouling system arranges a piping member having a plurality of openings outside the hull and allows the antifouling composition such as sodium hypochlorite to be discharged through the opening.

However, the piping member disposed outside the hull acts as a resistance when sailing the ship, and when an external force is applied, deformation or damage occurs, so that it is difficult to discharge a certain amount of antifouling composition for each opening.

The present invention is to solve the above problems, it is an object of the present invention to provide an antifouling system and a control method thereof that can reduce the cost in configuring an antifouling system.

Still another object of the present invention is to provide an antifouling system and a control method thereof so that the antifouling system does not act as a resistance when sailing a ship.

The antifouling system according to the present invention is provided with a ballast tank for storing a ballast water (ballast water), a ballast water treatment apparatus for generating a sterilizing material for sterilizing marine life contained in the ballast water flowing into the ballast tank; And an injector for injecting ballast water discharged from the ballast tank to the hull surface of the vessel.

In addition, the ballast tank may further include a neutralizing device for reducing the concentration of the sterilization material contained in the ballast water discharged from the ballast tank and a filtration device for filtering the marine organisms contained in the ballast water flowing into the ballast tank.

In addition, the ballast water treatment device may further include a supply pipe for supplying the sterilizing material generated in the filtration device.

The apparatus may further include a membrane filter for filtering and purifying sewage generated in the vessel, and a supply pipe for supplying the sterilizing substance generated in the ballast water treatment apparatus to the membrane filter.

In addition, the injector is connected to the ballast tank and extends in the front and rear and left and right directions of the vessel, a plurality of branch pipes branched from the extension pipe, the ballast discharged from the ballast tank surface of the vessel It may be provided with a plurality of nozzles provided on each branch pipe in order to spray evenly.

In addition, on the extension pipe at least one of a concentration sensor for measuring the concentration of the sterilizing substance contained in the ballast water, a flow meter for measuring the flow rate of the ballast water flowing through the extension pipe, a pressure gauge for measuring the pressure of the ballast water flowing through the extension pipe The above can be installed.

In addition, it is preferable that a receiving groove is formed in the surface of the vessel so that the end of each nozzle is located on the same surface as the surface of the vessel or located inside the surface of the vessel.

In addition, the nozzle is fixed to the receiving groove and the injection space between the receiving groove and the nozzle may be formed in the injection space is injected.

In addition, the branch pipe may be extended so that the nozzle may be accessible to the receiving groove.

And on the branch pipe is preferably provided with a pressure regulating means for adjusting the pressure of the ballast water injected into the plurality of nozzles.

The control method of the antifouling system according to the present invention includes the step of injecting the sterilizing material into the ballast water flowing into the ballast tank, reducing the concentration of the sterilizing material contained in the ballast water, the ballast number containing the low concentration of the sterilizing material Spraying the surface of the hull.

The method may further include supplying the generated sterilizing material to a filtering device for filtering the marine organisms contained in the ballast water flowing into the ballast tank.

The method may further include supplying the generated sterilizing material to a membrane filtration device that filters the sewage generated from the vessel and purifies it.

According to the antifouling system according to the present invention, since the sterilizing substance generated in the ballast water treatment apparatus can be used in the antifouling system, the cost of constructing the antifouling system can be reduced.

In addition, since the nozzles constituting the antifouling system are not exposed to the outside of the hull, the antifouling system can be prevented from acting as a resistance when the ship is sailing.

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

1 is a diagram showing various devices provided in a ship according to an embodiment of the present invention, Figure 2 shows a ballast tank and an antifouling system according to an embodiment of the present invention.

As shown in FIG. 1, a ship according to an embodiment of the present invention has a ballast tank 100 provided in a ship for securing stability and balance of the ship.

A certain amount of seawater flows into the ballast tank 100 to maintain the balance of the ship according to the amount of cargo carried on the ship. The amount of seawater introduced into the ballast tank 100 is set based on the size of the vessel, but if the vessel is large, 10,000 tons or more of seawater may be introduced.

Filtration to filter the marine life contained in the seawater introduced into the ballast tank 100 in order to prevent the marine life is introduced into the ballast tank 100 with the seawater in the process of introducing the seawater into the ballast tank (100) Apparatus 110 is provided.

The reason for filtering the marine life introduced into the ballast tank 100 using the filtration device 110 is to prevent the marine life from moving to another area through the ballast water stored in the ballast tank 100. .

 When marine life moves to another area and is discharged to the ocean together with the ballast number stored in the ballast tank 100, it may cause serious ecosystem disturbance such as fluctuation of representative species, red tide occurrence, etc. The device 110 is provided to prevent marine life from entering the ballast tank 100.

The filtering device 110 filters the marine organisms introduced into the ballast tank 100 by using a filter having a mesh of a predetermined size. However, since it is difficult to reduce the mesh size of the filter to fine marine organisms such as plankton, there may be a limit in preventing marine organisms from entering the ballast tank 100 using only the filtering device 110. .

Therefore, in addition to filtering the marine life using the filtration device 110, the ballast water treatment device 120 for killing the marine life existing in the ballast tank 100 is further provided.

In the ballast water treatment apparatus 120, a method for treating marine organisms contained in the ballast water stored in the ballast tank 100, using ozone treatment method using ozone, and chemicals such as hydrogen peroxide (H ₂ O ₂ ). Chemical methods to be injected into the tank 100, methods such as electrolytic treatment using sodium hypochlorite (NaOCl) generated when seawater is electrolyzed may be used. In this embodiment, the ballast water treatment apparatus 120 will be described by way of example to treat marine life using an electrolytic treatment method.

 Electrolytic treatment using sodium hypochlorite is a method of killing marine life by converting sodium chloride (NaCl) contained in seawater into sodium hypochlorite (NaOCl) by electrolysis. Sodium hypochlorite has a high bactericidal effect and has a bactericidal effect against a wide range of microorganisms.

The ballast water treatment apparatus 120 includes an electrolysis unit (not shown) to electrolyze seawater to generate sodium hypochlorite (NaOCl).

The ballast water treatment device 120 may be installed on the inlet pipe 101 through which seawater flows into the ballast tank 100 to generate sodium hypochlorite by electrolyzing the ballast water flowing into the ballast tank 100. have. Alternatively, after receiving a portion of the seawater to generate sodium hypochlorite, the generated sodium hypochlorite may be supplied to the inlet pipe 101.

In addition, the filtration device 110 may be kept clean by supplying a sterile material such as sodium hypochlorite generated by the ballast water treatment device 120 to the filtration device 110.

The ballast water treatment apparatus 120 is filtered because the various marine organisms included in the seawater are filtered and the marine organisms filtered by the filter 110 can breed in the state attached to the filtration apparatus 110. By supplying the sterilizing material generated in the filtering device 110, it is possible to prevent the breeding of marine organisms filtered by the filtering device (110).

In order to supply the sterilizing material generated from the ballast water treatment device 120 to the filtration device 110, a supply pipe 121 is provided to connect the ballast water treatment device 120 and the filtration device 110. The sterilizing material supplied through the supply pipe 121 enters the filtration device 110 and kills marine life, and then is discharged through the discharge pipe 111 of the filtration device 110.

Ship according to an embodiment of the present invention may be provided with a sewage treatment device 130 for treating various kinds of household sewage, including manure generated in the vessel in a biochemical manner.

The water treated by the sewage treatment device 130 is purified after passing through the membrane filtration device 131, the washing water used when washing dishes, the toilet water used when using the toilet, the cleaning used when cleaning It is used for water.

The membrane filtration device 131 is purified by the secondary treatment of the water first treated in a biochemical manner by the sewage treatment device 130 through membrane filtration.

At this time, the surface of the membrane provided in the membrane filter 131 may be kept clean by supplying a sterilizing substance such as sodium hypochlorite generated by the ballast water treatment device 120 to the membrane filter 131. In addition, the purified water in the membrane filtration device 131 is sterilized to suppress the growth of bacteria or microorganisms.

In order to supply the sterilizing material generated from the ballast water treatment device 120 to the membrane filter 131, a supply pipe 122 is connected to the ballast water treatment device 120 and the membrane filter device 131.

Meanwhile, sterilizing substances such as sodium hypochlorite generated by the ballast water treatment apparatus 120 are introduced into the ballast tank 100 together with seawater to kill marine organisms present in the ballast tank 100. In order to kill the marine organisms present in the ballast tank 100, it is preferable to maintain the concentration of sodium hypochlorite in the ballast tank 100 to about 5 ~ 10ppm.

When the ballast water in which the sterilizing substance stored in the ballast tank 100 is mixed is discharged as it is to the sea, marine life of the sea area where the ballast water is discharged may be killed. Therefore, before the ballast water stored in the ballast tank 100 is discharged to the sea is provided with a neutralizing unit 140 for reducing the concentration of the sterilizing material contained in the ballast water.

The neutralizing device 140 preferably maintains the concentration of the sterilizing material such as sodium hypochlorite contained in the ballast water discharged from the ballast tank 100 at 0.5 ppm or less.

And the ballast water discharged from the ballast tank 100 is used to build an antifouling system for preventing marine life such as barnacles, sea urchins and mussels attached to the hull.

In order to use the ballast water discharged from the ballast tank 100 in the antifouling system as described above is provided with an injection device 150 for injecting the ballast water discharged from the ballast tank 100 to the surface of the hull.

Hereinafter, with reference to Figure 2 will be described in more detail with respect to the ballast tank 100 and the injection device 150 constituting the antifouling system according to an embodiment of the present invention.

When the seawater is taken in and the ballast water is filled in the ballast tank 100, the seawater is sucked from the intake unit 102 using the ballast pump 105 and sent to each ballast tank 100 through the inflow pipe 101. At this time, each ballast tank 100 may be filled with a different amount of ballast number in order to balance the ship according to the amount of cargo carried on the vessel.

The filtration device 110 and the ballast water treatment device 120 and the like are installed on the inflow pipe 101. In addition, a bypass conduit 103 for bypassing the inlet conduit 101 provided with the filtration device 110 and the ballast water treatment device 120 is provided. The neutralizing device 140 described above may reduce the concentration of the sterilizing material contained in the ballast water flowing through the bypass pipe 103.

A flow path switching valve 104 is installed at a portion where the inflow line 101 and the bypass line 103 cross each other. When the ballast water flows into the ballast tank 100, the flow path switching valve 104 causes the ballast water to flow through the inflow pipe 101 in which the filtration device 110 and the ballast water treatment device 120 are installed. When discharged from the 100, the flow path is changed to be discharged through the bypass pipe (103).

Therefore, when seawater is introduced into the ballast tank 100, the marine organisms contained in the seawater are filtered by the filtration device 110 and the ballast water treatment device 120, and at the same time, the sterilizing substance such as sodium hypochlorite is ballast tank 100. When the ballast water is discharged from the ballast tank 100, the concentration of the sterilizing substance is weakened by the neutralizer 140.

In addition, the branch pipe 106 branched to each ballast tank 100 from the inflow pipe 101 is provided with an opening / closing valve 107 so as to adjust the amount of ballast water flowing into each ballast tank 100.

On the other hand, the injection device 150 for using the ballast water discharged from the ballast tank 100 as an antifouling system is connected to the ballast tank 100 and the extension pipe 151 extending in the front and rear and left and right directions of the vessel, respectively; And a plurality of nozzles 152 connected to the extension pipe 151 to spray the ballast water evenly on the surface of the ship.

In FIG. 2, the nozzles 152 provided only on the side of the hull are shown. However, the plurality of nozzles 152 are substantially a surface below the draft line of the hull (part submerged when the ship floats in water), specifically, the hull. It is installed to spray the ballast water to the bottom and side of the.

The first flow path change valve 108 is installed in the inlet pipe 101, and the second flow path change valve 109 is installed in the extension pipe 151 to change the movement path of the ballast water sucked by the suction force of the ballast pump 105. ) Is installed.

When the seawater flows into the ballast tank 100, the ballast pump flows in the direction in which the ballast water flows into the ballast tank 100 after opening the first flow path switching valve 108 and closing the second flow path switching valve 109. Rotate 105. When the ballast water stored in the ballast tank 100 is supplied to the injector 150, the first flow path switching valve 108 is closed and the second flow path switching valve 109 is opened. Rotate the ballast pump 105 in the discharge direction from the).

On the extension pipe 151, a concentration sensor 161 for measuring the concentration of the sterilizing substance contained in the ballast water, a flow meter 162 for measuring the flow rate of the ballast water flowing through the extension pipe 151, and the extension pipe ( A pressure gauge 163 is installed to measure the pressure of the ballast water flowing through 151.

The concentration sensor 161 is installed on the extension tube 151 and the concentration of the sterilizing substance contained in the ballast water flowing through the extension tube 151 is measured only when the concentration of the sterilizing substance contained in the ballast water is 0.5 ppm or less. The ballast water is discharged through the extension pipe 151.

Meanwhile, when the ballast water discharged from the ballast tank 100 is sprayed through the plurality of nozzles 152, the ballast water may be sprayed only through some nozzles of the plurality of nozzles 152.

For example, the ballast water is first sprayed through the nozzles installed in the ship corresponding to the odd numbered ballast tank 100, and then the nozzles installed in the ship and the corresponding ballast tank 100 correspond to the even ballast tank 100. The ballast water can be sprayed through.

When the ballast water is injected through some of the nozzles 152 as described above, when the excessive amount of ballast water is supplied to the nozzle 152, the nozzle 152 may be overloaded. The flow meter 162 and the pressure gauge 163 prevents an excessive amount of ballast water from being supplied to the nozzle 152 by checking the flow rate and pressure of the ballast water flowing through the extension pipe 151.

On the other hand, when the ballast water is injected through all the nozzles 152 installed in the ship, the nozzle 152 installed close to the ballast pump 105 takes a strong water pressure while the nozzle 152 installed far from the ballast pump 105. ) Is subjected to weak hydraulic pressure.

In this case, the pressure adjusting means for adjusting the pressure of the ballast water sprayed from the nozzle 153 on the branch pipe 153 branched from the extension pipe 151 so that the pressure of the ballast sprayed through each nozzle 152 is constant ( 155 is installed. As the pressure regulating means 155, a boosting device for increasing the pressure of the ballast water or a pressure reducing valve for lowering the pressure of the ballast water may be used.

Figure 3 shows a nozzle 152 according to an embodiment of the present invention is installed on the surface of the hull.

As shown in FIG. 3, when the nozzles 152 are installed in the hull, the end portions of the nozzles 152 are preferably located on the same plane as the surface of the hull or located inward of the surface of the hull. Thus, the receiving groove 170 for accommodating the nozzle 152 is formed on the surface of the hull such that the end of each nozzle 152 is located on the same plane or inside the surface of the hull.

The receiving groove 170 has a substantially trapezoidal shape and cutouts 152a are formed at both ends of the nozzle 152. The nozzle 152 is fixed to the receiving groove 170.

Therefore, an injection space 171 is formed between the accommodation groove 170 and the nozzle 152 to inject the ballast water through the injection space 171.

In this way, the nozzle 152 is installed in the receiving groove 170 so that the nozzle 152 does not protrude outward from the surface of the hull so that the nozzle 152 does not act as a resistance when sailing the ship.

Figure 4 shows the nozzle 152 according to another embodiment of the present invention is installed on the surface of the hull.

This embodiment is different from the embodiment described in FIG. 3 is that the nozzle 152 can enter and exit the receiving groove 170 formed on the surface of the hull.

As such, an apparatus (not shown) for moving the branch pipe 153 to allow the nozzle 152 to enter and exit the accommodation groove 170 may be provided. That is, the branch pipe 153 is formed to be extendable.

When the ship is sailing, as shown in (a), the nozzle 152 is accommodated inside the receiving groove 170, and when the ballast water is discharged from the ballast tank 100, the nozzle 152 as shown in (b) To be separated from the receiving groove 170.

Therefore, when the ship sails, the nozzle 152 may be prevented from acting as a resistance, and when the ballast water is injected, the ballast water may be effectively sprayed onto the surface of the hull.

Next, the control method of the antifouling system described above will be described with reference to the flowchart shown in FIG. 5.

First, the ballast water treatment device 120 generates a sterilizing material such as sodium hypochlorite (S110). The sodium hypochlorite can be generated using a method such as electrolysis of seawater.

Next, the sterilizing material generated by the ballast water treatment device 120 is introduced into the ballast tank 100 to kill marine organisms inside the ballast tank 100 (S120).

On the other hand, by supplying the sterilization material generated in the ballast water treatment device 120 to the filtration device 110 to kill the marine organisms filtered by the filtration device 110 (S130), or the sterilization material generated in the ballast processing device 120 It is supplied to the membrane filter device (131) (S140) to keep the surface of the membrane provided in the membrane filter device 131 clean and sterilize the purified water in the membrane filter device (131) to suppress the growth of bacteria or microorganisms .

Since the ballast water stored in the ballast tank 100 is discharged to the ocean, the concentration of the sterilizing substance contained in the ballast water is reduced before the ballast number is discharged to the ocean (S150).

And by spraying the ballast water containing a low concentration of sterilizing material to the surface of the hull (S160) to prevent the various marine life such as barnacles, sea urchins and mussels attached to the surface of the hull.

As described above, since the sterilizing material generated in the ballast water treatment apparatus 120 can be used in the antifouling system, the cost of constructing the antifouling system can be reduced. In addition, by preventing the nozzle 152 constituting the antifouling system from being exposed to the outside of the hull, it is possible to prevent the antifouling system from acting as a resistance when sailing the ship.

The antifouling system using the ballast water and the control method thereof according to the embodiment of the present invention have been described above, but the spirit of the present invention is not limited to the embodiments presented herein, and those skilled in the art who understand the spirit of the present invention Within the scope of the same idea, other embodiments may be easily proposed by adding, changing, deleting or adding components, but this will also fall within the scope of the present invention.

1 is a view showing a variety of devices provided in the ship according to an embodiment of the present invention.

Figure 2 is a plan view showing a ballast tank and an antifouling system provided in the vessel shown in FIG.

3 is a view showing a nozzle forming the antifouling system shown in FIG.

4 is a view showing a nozzle forming an antifouling system according to another embodiment of the present invention.

5 is a flow chart showing a control method of the antifouling system according to an embodiment of the present invention.

** Explanation of symbols for the main parts of the drawings **

100: ballast tank 110: filter device

120: ballast water treatment device 131: membrane filter

140: neutralizer 150: injector

Claims (14)

A ballast tank provided in the ship to store ballast water; A ballast water treatment device for generating a sterilizing material for sterilizing marine organisms contained in the ballast water flowing into the ballast tank; Injector for injecting the ballast water discharged from the ballast tank on the hull surface of the ship and It includes a neutralizing device for reducing the concentration of the sterilizing material contained in the ballast water discharged from the ballast tank, The injector, An extension pipe connected to the ballast tank and extending in the front-back direction and the left-right direction of the ship; A plurality of branch pipes branched from the extension pipe, A plurality of nozzles provided on each branch pipe to evenly spray the ballast water discharged from the ballast tank to the surface of the ship; And The antifouling system on the extension tube comprises a concentration sensor for measuring the concentration of the sterilizing substance contained in the ballast water. delete The method of claim 1, The antifouling system further comprises a filtration device for filtering marine life contained in the ballast water flowing into the ballast tank. The method of claim 3, The antifouling system further comprises a supply pipe for supplying the sterile material generated in the ballast water treatment device to the filtration device. The method of claim 1, A membrane filtration device for filtering and purifying sewage generated in the vessel; The antifouling system further comprises a supply pipe for supplying the sterilizing material generated in the ballast water treatment device to the membrane filter device. delete The method of claim 1, And at least one of a flow meter for measuring the flow rate of the ballast water flowing through the extension pipe and a pressure gauge for measuring the pressure of the ballast water flowing through the extension pipe. The method of claim 1, An antifouling system, characterized in that the receiving groove is formed on the surface of the vessel so that the end of each nozzle is located on the same surface as the surface of the vessel or located inside the surface of the vessel. The method of claim 8, The nozzle is fixed to the receiving groove, antifouling system, characterized in that the injection space is formed between the receiving groove and the nozzle is sprayed ballast water. The method of claim 8, And the branch pipe is extendable so that the nozzle can enter and exit the receiving groove. The method of claim 1, The antifouling system, characterized in that the pressure control means for adjusting the pressure of the ballast water injected into the plurality of nozzles on the branch pipe. delete delete delete

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