KR100478647B1 - Apparatus for anti-fouling and anti-corrosion - Google Patents

Abstract

The present invention relates to an antifouling and anticorrosive device for reducing structure contamination by marine organisms, wherein the antifouling electrode and the anticorrosive electrode are coupled together in one fixed portion; The fixing part includes a stud bolt penetrating the structure to be fixed to the structure and having a hollow in the axial direction; The power supply unit is electrically connected to the antifouling electrode and the anticorrosive electrode, respectively, through a wire inserted into the stud bolt and the hollow of the stud bolt to supply power to the antifouling electrode and the anticorrosive electrode; It is possible to reduce the space required for the installation of antifouling and anticorrosive devices, and thus it is possible to easily introduce antifouling and anticorrosive devices to ships and submersibles, such as small ships or small tanks, where the installation space is narrow.

Description

Antifouling and anticorrosion devices {APPARATUS FOR ANTI-FOULING AND ANTI-CORROSION}

The present invention relates to antifouling and anticorrosive devices for reducing structure contamination by marine organisms, and more particularly to antifouling and anticorrosive devices that can be mainly used in ships and submersibles, such as small ships or small tanks.

A large amount of seawater is introduced as cooling water for cooling devices such as desalination plants, seawater magnesia manufacturing plants, and power plants.However, due to the inflow of seawater, indicators such as mussels, barnacles, and sea horses are attached to and grow in the pipeline. There is a problem. In addition, surfaces such as pipelines react with seawater to generate corrosion.

This problem not only occurs in land-based plants, but also occurs in ships and the like. In other words, the vessel is required to supply seawater for cooling the engine and balancing the vessel (Ballast), the same problem occurs in the area where the seawater is supplied.

In order to solve this problem, the conventional technology is used in combination with the antifouling electrode and the anticorrosive electrode to prevent the contamination of the structure by marine life and at the same time to prevent the contamination of the structure by corrosion.

As a conventional technology related to the present invention, Korean Patent Application Publication No. 2001-0097221 "A marine life habitat prevention apparatus and method thereof", Korean Utility Model Registration No. 249437 "Preventing the attachment of marine life Apparatus ", International Publication No. WO 89/03261," Method for reducing marine biological pollution ", and the like.

According to the prior art, mainly copper (Cu) is used as an antifouling electrode, and aluminum (Al), iron (Fe), etc. are used as an anticorrosive electrode.

In addition, the anticorrosive electrode is known to have a certain antifouling effect as well as the anticorrosive effect, and is generally used together with the antifouling electrode.

1 and 2 is a schematic diagram of a conventional antifouling and anticorrosion apparatus.

1 is provided with a pair of antifouling anodes for injecting sea water into the tank to release copper ions and an anti-corrosion anode for emitting aluminum or iron ions. The supplying constant current automatic rectifier is electrically connected to the antifouling anode and the anticorrosion anode.

FIG. 2 relates to an antifouling and anticorrosion apparatus for seawater flowing into cooling water of a ship, and is the same technology as that of FIG. 1.

According to these conventional techniques, the antifouling electrode and the anticorrosive electrode are used while contacting with seawater, and the antifouling electrode and the anticorrosive electrode are fixed to a structure such as a hull or a tank by being coupled to a fixed part. At this time, the prior art provides a fixing unit for each electrode separately.

According to such a conventional structure, a large ship or a vessel having sufficient installation space such as a substitute tank or a submersible is not a big problem, but a small ship or a small tank such as a small installation space such as a ship and a submersible are fixed. As the space occupied by the space became larger, it was difficult to secure the installation space required for the antifouling and anticorrosion devices.

 That is, in order to use the antifouling electrode and the anticorrosive electrode together, a fixing part must be provided for each electrode. Therefore, two fixing parts are required to construct a conventional antifouling and anticorrosion device. There is a problem in that it is difficult to apply antifouling and anticorrosive devices to ships and submersibles that have a small installation space such as a small ship or a small tank because it requires a very large space.

The present invention has been made in view of the above problems, by providing an antifouling and anticorrosive device that can significantly reduce the space required for the installation of antifouling and anticorrosive devices by combining the antifouling electrode and the anticorrosive electrode in one fixed portion. I would like to.

In order to solve the above problems, the present invention, the electrode for antifouling used in contact with sea water in order to prevent the marine life to grow on the structure, the electrode for anticorrosion used in contact with the sea water to prevent corrosion of the structure, Fixed parts fixed to the structure by being coupled to the electrodes, respectively, to fix the antifouling electrode and the anticorrosive electrode to the structure, and a power supply unit supplying power to the antifouling electrode and the anticorrosive electrode. An antifouling and anticorrosion device comprising: the antifouling electrode and the anticorrosive electrode are coupled together in one fixing part.

In the above, it is preferable that an insulator for electrical insulation between the antifouling electrode and the anticorrosive electrode is inserted between the antifouling electrode and the anticorrosive electrode.

In the above, the fixing portion penetrates the structure to be fixed to the structure, and at least two fastening fastened to the stud bolt to secure the stud bolt and the stud bolt to the inner and outer walls of the structure to form a hollow in the axial direction And a nut, wherein the power supply unit supplies power to the antifouling electrode and the anticorrosive electrode through the wire inserted into the stud bolt and the hollow of the stud bolt. It is preferable to be electrically connected to each.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

3 is a cross-sectional view of the coupling portion and the electrode according to an embodiment of the present invention.

The lower part of the structure 10 is in contact with sea water.

The stud bolt 150 penetrates the structure 10 and protrudes to the outside of the structure 10, that is, to the seawater side.

The stud bolt 150 is coupled to the anti-corrosion electrode 20 and the antifouling electrode 30.

The antifouling electrode 30 is used in contact with the sea water to prevent marine life from engrafting the structure 10, the anticorrosive electrode 20 is used in contact with the sea water to prevent the structure 10 is corroded. .

An insulator 131, 132, 133 is inserted between the stud bolt 150 and the structure 10 to electrically insulate the structure 10 and the fixing part.

An insulator 141, 142, 143 is inserted between the anticorrosive electrode 20 and the antifouling electrode 30 to electrically insulate the anticorrosive electrode 20 and the antifouling electrode 30.

The insulator 142 has threads formed on the outer circumferential surface and the inner circumferential surface, and the inner circumferential surface of the insulator 142 is screwed with the stud bolt 150, and the outer circumferential surface of the insulator 142 is screwed with the antifouling electrode 30.

The insulator 143 is particularly inserted between the stud bolt 150 and the antifouling electrode 30 to electrically insulate the stud bolt 150 and the antifouling electrode 30 electrically connected to the anticorrosive electrode 20. .

Anticorrosive electrode 20 is in electrical contact with the stud bolt 150 in contact with the outer peripheral surface of the stud bolt 150, the power supply unit (not shown) by a fastening nut 161 provided on the top of the stud bolt 150 Is electrically connected).

A hollow is formed along the axial direction of the stud bolt 150, the wire 160 is inserted into the hollow.

The wire 160 is connected to the inside of the structure 10 along the axial direction of the stud bolt 150 from the anchor 31 provided in the antifouling electrode 30 is connected to the power supply (not shown).

 The fastening nut 162 is screwed to the outer circumferential surface of the stud bolt 150 at the upper portion of the fastening nut 161 to prevent the fastening of the fastening nut 161, the fastening nut 163 is stud together with the fastening nut 161 The bolt 150 is fixed to the structure 10 and at the same time to fix the anti-corrosion electrode 20 together with the antifouling electrode 30.

Reference numeral 170 is a washer.

Reference numerals 191 and 192 denote O-rings.

Reference numerals 181 and 182 denote heat shrink tubes, which prevent seawater from flowing between the electrodes.

The power supply unit supplies DC power to the anticorrosive electrode 20 through the fastening nut 161 and the stud bolt 160, and the power supply unit also supplies the antifouling electrode 30 through the wire 160 and the anchor 31. Supply DC power to.

Therefore, aluminum (Al) ions or iron (Fe) ions are released from the corrosion-resistant electrode to prevent corrosion of the structure, and copper (Cu) ions are released from the antifouling electrode to prevent the engraftment of marine life.

In consideration of the fact that the antifouling electrode requires more current than the anticorrosive electrode, the antifouling electrode allows current to be supplied through the wire, while the anticorrosive electrode uses a contact between the stud bolt and the electrode.

One embodiment of the present invention as described above is only a preferred embodiment of the present invention, the technical idea of the present invention can be variously changed or adjusted by those skilled in the art, if such a change or adjustment uses the technical idea of the present invention It is within the scope of the present invention.

The present invention can reduce the space required for the installation of the antifouling and anticorrosive device by combining the antifouling electrode and the anticorrosive electrode together in one fixing portion, and thus the ship and submersible such as a small ship or a small tank, etc. Antifouling and anticorrosion devices can be easily introduced.

In addition, when the present invention is introduced in an antifouling and anticorrosion apparatus having the same capacity, it is possible to reduce costs due to the simplification of the manufacturing process.

1 is a schematic diagram of a conventional antifouling and anticorrosion apparatus.

2 is a schematic diagram of another conventional antifouling and anticorrosion device.

3 is a cross-sectional view of the coupling portion and the electrode according to an embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

10 structure 20 anticorrosive electrode

30: antifouling electrode 150: stud bolt

Claims (3)

Antifouling electrodes used in contact with seawater to prevent marine organisms from living on the structure, anticorrosive electrodes used in contact with seawater to prevent corrosion of the structure, the antifouling electrodes and the anticorrosive electrodes In the antifouling and anticorrosive device comprising a fixed portion coupled to the electrodes and fixed to the structure to be fixed to the structure, and a power supply for supplying power to the antifouling electrode and the anticorrosive electrode: The antifouling electrode and the anti-corrosion electrode are coupled together in one fixing part; The fixing part includes a stud bolt penetrating the structure to be fixed to the structure and having a hollow in the axial direction; The power supply unit is electrically connected to the antifouling electrode and the anticorrosive electrode, respectively, through a wire inserted into the stud bolt and the hollow of the stud bolt to supply power to the antifouling electrode and the anticorrosive electrode; Antifouling and anticorrosion device, characterized in that. The antifouling and anticorrosion device according to claim 1, wherein the fixing part further comprises at least two fastening nuts fastened to the stud bolts for fixing the stud bolts on the inner and outer walls of the structure. delete