KR20190046540A - Device for preventing attachment of marine life using sea water cells - Google Patents

Abstract

Disclosed is a marine organism attachment prevention device using seawater cells. According to the present invention, the marine organism attachment prevention device includes: a seawater cell for storing electric energy in a battery; a power supply control part for intermittently supplying the electric energy to a consumer; a plurality of cathodic and anodic members installed on the surface of a marine facility or plant or a vessel which touches the seawater; and a distributing part for enabling a current to flow between the cathodic and anodic members. According to the present invention, a considerable reduction in cost for the maintenance of a marine facility or plant or a vessel can be made.

Description

TECHNICAL FIELD [0001] The present invention relates to a device for preventing the attachment of marine life using a sea water cell,

More particularly, the present invention relates to an apparatus for preventing the attachment of marine organisms using a seawater cell, and more particularly, to an apparatus for preventing the attachment of marine organisms using a seawater cell, To prevent marine organisms from adhering to the surfaces of ships and other plants and other marine facilities, and to an apparatus for preventing marine organisms from attaching marine organisms that can easily remove attached marine organisms.

Generally, in the process of building a ship, the period of work on the quay to install the equipment after the launch is several months to several months. In the process of drying a ship moored at the seawall, a large number of marine life such as oysters, barnacles, sea anemones, and seaweed, which are attached to rocks, are inhabited in the water near the seawall. Seaweeds of marine creatures swim and swim in search of adherent substrates and attach to the lower part of the hull of the ship, which is an adherent substrate.

In this way, marine life in the sea is attached to the lower part of the ship's hull, and the attached marine life is also called fouling in shipbuilding marine terminology.

As described above, when the ship is moored at the seawall and the ship is dried for a short period of time, the polling is not attached. However, the polling attaches to the ship during the operation period of several months. When the polling is attached, the diver is usually removed by using a brush or the like or removed by using an underwater robot. When there is a lot of polling, re-docking with the dock is performed to remove the polling There is a considerable inefficiency in that a lot of manpower input due to necessity, a long working time and an excessive cost are incurred.

This phenomenon occurs not only in vessels, but also in plants and marine facilities.

Conventionally, in order to prevent marine organisms from adhering to the ship during the drying process, a method of coating paints or materials for air pollution on the outer surface of the hull has been used. However, In addition, the anti-fouling paints and materials are designed to prevent the polling by using the flow of seawater generated during the operation of the ship, which is a disadvantage in that it is not suitable for application to a pending vessel.

As another conventional technique, Japanese Patent Application Laid-Open No. 61-143587 discloses a method of electrolyzing seawater to generate a chlorine-based disinfectant to remove marine organisms. However, the method is complicated in structure and efficiently attaches marine organisms There is a problem that it can not be removed.

. Japanese Patent Application Laid-Open No. 61-143587

It is an object of the present invention to provide a method and apparatus for supplying electrical energy generated from a sea water cell to a surface of a vessel, a plant, and other marine facilities exposed to seawater to generate electric shock (such as flowing a microcurrent to generate electrical stimulation) It is an object of the present invention to provide a means for allowing attached marine organisms to move to other places by electric stimulation as well as to prevent the organisms from adhering to surfaces of ships and other plants or other marine facilities.

Another object of the present invention is to provide a means for preventing marine organisms from adhering to the inside or outside of a sea water cell exposed to seawater because the sea water cell generating electric energy is always exposed to seawater have.

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to at least partially solve the problems in the conventional arts. It can be understood.

The object is achieved by a seawater cell for producing electrical energy from seawater and storing the produced electrical energy in a battery, according to the present invention; A power supply controller for supplying electric energy stored in the battery intermittently to a user using a timer; A plurality of cathode members and anode members paired with each other on a surface of a ship, plant or marine facility in contact with seawater and installed at predetermined intervals in parallel; And a power source supplied from the power supply control unit is distributed to each of the cathode member and the anode member so that electrical impact is applied to the marine life attached to the surface between the anode member and the anode member, And a distribution unit for allowing the electric current to flow through the electrolytic cell.

An insulating member may be provided between the cathode member and the anode member which are coupled to each other.

A plurality of discharge protrusions for guiding the flow of current may be formed on the surface of the cathode member and the anode member facing each other which are spaced apart from each other.

A mesh member made of a conductor is electrically connected to the cathode member and the anode member so that a current flows through the entire region between the cathode member and the anode member on the surface of the cathode member and the anode member, Can be connected and installed.

According to the present invention, electric energy generated from a seawater cell is stored in a battery, and the stored power is supplied to a cathode member and an anode member provided on the surface of a ship, plant, and other marine facilities exposed to seawater, And thus marine organisms that are sensitive to minute currents can be removed from the surface of vessels and other plant and other marine facilities as well as the attached marine organisms can be moved to other places by electrical stimulation And the like.

In addition, it is possible to easily remove marine organisms attached to a ship, a plant or an ocean facility, and to suppress the adhesion, thereby providing a remarkable reduction in the maintenance cost of a ship, a plant or an ocean facility .

In addition, since an electrode member for generating an electric field is provided on the outer surface or inside of the sea water cell generating electric energy, the marine life can be prevented from being attached to the sea water cell exposed to the sea water at all times, It is possible to provide an effect that the efficiency may be improved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram for explaining an apparatus for preventing marine biofilm attachment using a sea water cell according to a first embodiment of the present invention; FIG.
2 is a schematic block diagram for explaining an apparatus for preventing marine biofilm attachment using a seawater cell according to a second embodiment of the present invention.
FIG. 3 is a schematic block diagram for explaining an apparatus for preventing marine biofilm attachment using a sea water cell according to a third embodiment of the present invention.
4 is a schematic block diagram for explaining a control unit of a marine organism attachment preventing apparatus using a seawater cell according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, the well-known functions or constructions are not described in order to simplify the gist of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic block diagram for explaining an apparatus for preventing marine organisms attachment using a seawater cell according to a first embodiment of the present invention; Fig.

As shown in FIG. 1, an apparatus 10 for preventing marine organisms adhering using a seawater cell according to the present invention includes a seawater battery (not shown) for producing electrical energy from seawater and storing the produced electrical energy in battery 22 A power supply control unit 30 for supplying electric energy stored in the battery 22 intermittently to a place of use by providing a timer 32, A plurality of negative electrode members 40A and an anode member 40B provided in parallel at predetermined intervals so as to apply electric shock to the marine life attached to the surface between the negative electrode member 40A and the positive electrode member 40B A distribution unit for distributing a power supplied from the power supply control unit 30 to each of the anode member 40A and the anode member 40B so that a current flows between the anode member 40A and the anode member 40B 50) Eojinda.

This will be described more specifically.

The seawater cell 20 extracts sodium ions from the seawater, stores it as a cathode material, and reacts the water with an anode to produce electric energy. The principle and structure of the seawater cell 20 are well known, Is omitted.

The number of the sea water cells 20 may be one, but it is preferable that the number of the sea water cells 20 is plural. That is, it is also possible to store the electric energy produced from the plurality of sea water cells 20 in the battery 22.

The electric energy produced by the above-described seawater cell 20 is stored in the battery 22.

The power supply control unit 30 is a unit for applying electric energy stored in the battery 22 to the distribution unit 50 to be used for intermittent use by the timer 32. The timer 32 includes a timer 32, And is electrically connected to the battery 22 of the battery 20. The power supply control unit 30 includes a microcomputer for performing an arithmetic operation as well as an on / off switch. The micom is operated to measure the capacity (mAh) of the electric energy stored in the battery 22 and to control and supply the intensity of the current or voltage applied to the distribution unit 50 based on the measured capacity.

Each of the cathode member 40A and the anode member 40B is installed in parallel on a surface of a ship, a plant, or an ocean facility contacting with seawater at a predetermined interval in pairs. As shown in FIG. 1, And are arranged at predetermined intervals from one another. At this time, an insulating member 60 is provided between the anode member 40A and the anode member 40B which are coupled to each other.

The negative electrode member 40A and the positive electrode member 40B are coupled to each other with the insulating member 60 interposed therebetween and the pair of the negative electrode member 40A and the positive electrode member 40B, And are arranged to face each other with a predetermined gap therebetween.

The shapes, sizes, number, and lengths of the cathode member 40A and the anode member 40B vary depending on the size and other conditions of the place where the apparatus 10 for preventing marine organisms attachment using the seawater cell according to the present invention is installed The anode member 40A and the anode member 40B are elongated in a strip shape and are spaced approximately 0.5 to 5 cm apart from each other. This is because the negative electrode member 40A and the positive electrode member 40B are formed in a strip shape so that a current can flow in a wider surface area (a surface of a ship or an ocean facility to which marine life is attached). In the case where the cathode member 40A and the anode member 40B are coupled to each other to form a pair, if the distance between the adjacent pair is 0.5 cm or less, the cathode member 40A and the anode member 40B When installed at an interval of 5 cm or more, high power is required. Therefore, the interval between the cathode member 40A and the anode member 40B is set according to the degree of the supplied power source and the size of the installation place.

The negative electrode member 40A and the positive electrode member 40B may be made of a thin plate made of copper or a copper alloy or the like but made of a material that does not corrode the seawater, and each of the negative electrode member 40A and the positive electrode member 40B 40B are arranged in parallel.

The distribution unit 50 distributes the power supplied from the power supply control unit 30 to each of the negative electrode member 40A and the positive electrode member 40B and applies the power supplied from the power supply control unit 30 The current is distributed between the cathode member 40A and the anode member 40B by applying the distribution to each of the anode member 40A and the anode member 40B.

This distribution portion 50 may be configured such that power is supplied to each of the cathode member 40A and the anode member 40B in order and power is simultaneously supplied to each of the cathode member 40A and the anode member 40B .

 If the distributor 50 is configured to supply power to each of the cathode member 40A and the anode member 40B in turn, there is a distributing circuit electrically interrupted in the distributor 50 .

The operation of the apparatus 10 for preventing marine organisms attachment using the sea water cell constructed as described above will be described.

The electric energy generated from the sea water cell 20 is stored in the battery 22.

The electric energy stored in the battery 22 is supplied to the distribution unit 50 by the power supply control unit 30. The distribution unit 50 applies power supplied from the power supply control unit 30 to each of the cathode member 40A and the anode member 40B.

When the electric energy produced from the sea water cell 20 is applied to the cathode member 40A and the anode member 40B in the above-described process, the surface area between the anode member 40A and the anode member 40B facing each other S). That is, when power is applied to the cathode member 40A and the anode member 40B, a minute current flows in the surface region S between the cathode member 40A and the anode member 40B.

The current flows in the surface region S because the seawater serves as a conductor. That is, the sea water acts as a conductor for charge transfer between the cathode member 40A and the anode member 40B.

The current (or a minute current) flows through the surface region S between the cathode member 40A and the anode member 40B facing each other in the above-described process, so that the marine organisms attached to the surface region S are discharged to the marine environment As shown in FIG. That is, when a current flows in the surface area S between the cathode member 40A and the anode member 40B, the surface area S between the cathode member 40A and the anode member 40B, as well as the surface area S between the cathode member 40A and the anode member 40B, 40A) and the anode member (40B) themselves, stimulating the marine life on the surface of the ship or marine facilities, so that current-sensitive marine life is removed from the surface of the ship or marine facilities .

Since electric power is intermittently supplied from the power supply control unit 30, an electric field is periodically formed in the cathode member 40A, the anode member 40B, and the surface region S, and thus affects floating marine life, It is possible to positively prevent the adherence of the larvae.

2 is a schematic block diagram illustrating an apparatus for preventing marine biofilm attachment using a seawater cell according to a second embodiment of the present invention.

As shown in FIG. 2, the apparatus 10 for preventing marine organisms attachment using a seawater cell according to the second embodiment comprises a cathode member 40A and a cathode member 40B, Except that a plurality of discharge protrusions 42 for inducing the flow of current are protruded in the direction facing each other.

2, a plurality of discharge projections 42 for guiding current flow are formed on the surface of the cathode member 40A and the anode member 40B facing each other, The distance between the discharge protrusions 42 formed on the cathode member 40A and the discharge protrusions 42 formed on the anode member 40B becomes close to each other, The current flows more easily than the other regions. Therefore, not only can the detachment of the marine life attached to the surface of the ship or the marine facilities be easily induced, but also the marine life of floating marine life is adhered to the cathode member 40A, the anode member 40B and the surface region S It is possible to induce the user to move to another place.

3 is a schematic block diagram illustrating an apparatus for preventing marine biofilm attachment using a sea water cell according to a third embodiment of the present invention.

3, the apparatus 10 for preventing marine organism attachment using a seawater cell according to the third embodiment includes a cathode member 40A and a cathode member 40B, A mesh member 70 made of a conductor is electrically connected to the cathode member 40A and the anode member 40B so that a current can flow in the entire region S1 between the anode member 40B and the anode member 40A. And are installed in the same manner as in the above embodiment.

As described above, since the mesh member 70 made of a conductor is provided between the cathode member 40A and the anode member 40B in electrical connection with the anode member 40A and the anode member 40B, The applied power source flows through the anode member 40A and the anode member 40B on both sides through the mesh member 70 provided in the region S1. Therefore, since an electric field is formed in the region where the mesh member 70 is provided, as well as the anode member 40A and the anode member 40B, the marine adhering to the region S1 between the anode member 40A and the anode member 40B The creature can be eliminated due to the influence of the electric field.

FIG. 4 is a schematic block diagram illustrating a control unit of a marine organism attachment preventing apparatus using a seawater cell according to the present invention. Referring to FIG.

As shown in FIG. 4, the apparatus for preventing marine organisms adhering 10 using the seawater cell according to each embodiment of the present invention described above can be applied to a marine organism attachment preventing apparatus 10 using each sea water cell, The present invention is the same as the above-described embodiment except that the control unit 100 is configured to be installed in the facilities, respectively.

As described above, by controlling each of the marine organism attachment preventing apparatus 10 using the respective seawater cells with one control unit 100, it is possible to effectively prevent the marine organisms from adhering to surfaces of ships, plants, .

Although not shown in the drawing, an apparatus 10 for preventing marine organisms adhering to the sea using the seawater cell according to the present invention includes a seawater cell 20, which is always exposed to seawater, as an electrode member for forming an electric field for forming an electric field, A cathode member for a battery and an anode member may be provided. The cathode member and the anode member for a sea water battery may be provided with a discharge protrusion or a mesh member. The anode member and the cathode member for a seawater battery 20 may be installed on the outer surface and inside the case of the sea water battery 20.

Since the cathode member and the anode member for the sea water battery are installed in the case of the sea water cell 20 and the power is supplied from the distribution portion 50, an electric field is formed also in the sea water cell 20, 20 can be prevented from attaching marine life.

As described above, by installing the apparatus 10 for preventing marine organisms from attaching to the surface exposed to seawater such as the surface of a ship, a plant, a marine facility, etc., it is possible not only to easily remove marine organisms attached thereto , It is possible to prevent the floating marine life from being attached.

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 embodiments, but, on the contrary, It is obvious to those who have. Accordingly, it should be understood that such modifications or alterations should not be understood individually from the technical spirit and viewpoint of the present invention, and that modified embodiments fall within the scope of the claims of the present invention.

10: Device for preventing attachment of marine organisms 20: Sea water cell
22: battery 30: power supply control unit
32: Timer 40A: negative electrode member
40B: anode member 42: discharge projection
60: Insulation member 70: Mesh member

Claims (4)

A seawater cell for producing electrical energy from seawater and storing the produced electrical energy in the battery;
A power supply controller for supplying electric energy stored in the battery intermittently to a user using a timer;
A plurality of cathode members and anode members paired with each other on a surface of a ship, plant or marine facility in contact with seawater and installed at predetermined intervals in parallel; And
A power source supplied from the power supply control unit is distributed to each of the cathode member and the anode member so that electrical impact is applied to the marine life attached to the surface between the cathode member and the anode member, And a distributor for distributing the electric power to the electric motor.
An apparatus for preventing the attachment of marine organisms using seawater cells. The method according to claim 1,
Characterized in that an insulating member is provided between the cathode member and the anode member which are coupled to each other in pairs.
An apparatus for preventing the attachment of marine organisms using seawater cells. 3. The method of claim 2,
Wherein a plurality of discharge protrusions for guiding a current flow are protruded in a direction facing each other on the surface of the cathode member and the cathode member facing each other,
An apparatus for preventing the attachment of marine organisms using seawater cells. 3. The method of claim 2,
A mesh member made of a conductor is electrically connected to the cathode member and the anode member so that a current flows through the entire region between the cathode member and the anode member on the surface of the cathode member and the anode member, Wherein the first, second,
An apparatus for preventing the attachment of marine organisms using seawater cells.

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