KR101040204B1 - Self energy-generating electrolytic protection system - Google Patents

Abstract

The present invention relates to a self-generating electric system for the metal structure installed in the sea, more specifically, using an external power method, but converts the kinetic energy by the waves into electrical energy without using a battery that needs to be replaced The present invention relates to a self-generating electric system used as a power source.

According to an aspect of the present invention, there is provided an electric type system of a metal structure installed at sea, comprising: power generation means for applying an anticorrosive current to the metal structure to convert the kinetic energy of seawater into electric energy; An anode part for injecting anticorrosive current into the metal structure, the anode part being electrically connected to the anode terminal of the power generating means and the other end embedded in the surrounding sea water of the metal structure; A cathode wire connecting the anode terminal of the power generation means and the anode portion; A cathode wire connecting the cathode terminal of the power generation means and the metal structure; And a floating body which accommodates a portion of the power generating means, the anode wire, and a portion of the cathode wire therein and surrounds the outer circumference of the metal structure, and the other end of the anode wire is buried in sea water. It is preferable to include;

Description

Self energy-generating electrolytic protection system

The present invention relates to a self-generating electric system for the metal structure installed in the sea, more specifically, using an external power method, but converts the kinetic energy by the waves into electrical energy without using a battery that needs to be replaced The present invention relates to a self-generating electric system used as a power source.

The electric method is to prevent corrosion by giving a metal a constant potential, and can also be expressed as inhibiting the anodic reaction, which is a corrosion reaction, by artificially controlling the potential of the object to be corrosion. When a metal is corroded, a kind of battery reaction generally occurs, so that a large part of the ionization tends to be dissolved. On the contrary, the metal is prevented from being corroded by giving a floating potential to the metal. The method of giving an anodic current to the object is called an anode method and the method of preventing corrosion by giving a cathode current is called a cathode method.

The electric method is divided into two types, the sacrificial anode method and the external power method, depending on the method of supplying the method current. The sacrificial anode method is a method based on the potential difference between the anode itself and the ferrous metal itself, and the external power method installs the anode in the electrolyte (sea water, soil, fresh water, etc.) in which the object is placed and separates it from the outside. The anode of the supplied DC power is connected and the cathode is connected to the to-be-tested object to supply the anticorrosive current, which is commonly used for external power.

On the other hand, as shown in Figure 1, when installing the offshore structure (OS; Offshore Structure) to install a metal structure (SS; Steel Structure) supporting the offshore structure (OS) together, typically the metal structure For SS, steel pipe pile foundations are used.

Since the metal structure (SS) is part of the state is submerged in the seawater as shown in the drawing, the electric method is used. The conventional electric method is a system using the external power method, the fixture (1), the power ( 2), cathode line 3, anode line 4 and anode 5, an example of which is shown in FIG.

The fixture 1 used in the electrical apparatus shown in FIG. 2 is a tube-shaped structure fixed to a metal structure (SS), and a power source 2, a part of a cathode ray 3, and an anode ray 4 therein. Since the positive electrode 5 should always be submerged in seawater, which is an electrolyte, the positive electrode 5 is always submerged in water by determining the length of the positive electrode line 4 in consideration of the difference in tides.

As the anode 5, an iron anode, a high silicon iron anode, a platinum anode, a soft-silver anode, a mixed oxide anode, a mesh anode, or the like may be used.

In the conventional electric system, there is a problem that requires maintenance, which is a problem of the external power method. Since a power supply is always needed, the battery used as the power source must be replaced periodically. Therefore, there is a problem that the cost, manpower consumption, the risk of safety accidents in the battery replacement process.

The present invention has been drawn to solve the above problems, the problem to be solved by the present invention is to provide a self-generating electric system that can supply a continuous power without using a battery by building a self-generating system There is.

The present invention as a means of solving the problem to be solved by the present invention,

In the electric system of a metal structure installed at sea,

Power generation means for applying anticorrosive current to the metal structure and installed in the metal structure to convert kinetic energy of seawater into electrical energy;

An anode part for injecting anticorrosive current into the metal structure, the anode part being electrically connected to the anode terminal of the power generating means and the other end embedded in the surrounding sea water of the metal structure;

A cathode wire connecting the anode terminal of the power generation means and the anode portion;

A cathode wire connecting the cathode terminal of the power generation means and the metal structure; And,

A float floating in the surface of the power generating means, a portion of the anode wire and a portion of the cathode ray provided therein and surrounding the outer circumference of the metal structure and allowing the other end of the anode wire to be embedded in sea water; It is preferable to include.

The power generation means,

It provides a self-powered electric system comprising a pressing means for pressing the piezoelectric element by the vertical movement of the piezoelectric element and the buoyancy body.

The pressing means,

A spring provided inside the buoyancy body and having one end fixed thereto;

It is preferable to include a weight body installed at the other end of the spring and provided at a position capable of pressing the piezoelectric element.

The power generation means,

A spring provided inside the buoyancy body and having one end fixed thereto;

A permanent magnet installed at the other end of the spring,

Preferably, the permanent magnet is configured of a coil provided at a position capable of generating an induced current when the permanent magnet moves by vertical motion of the buoyancy body.

A power storage means accommodated in the floating body and accumulating electric power produced by the power generation means,

The anode portion is electrically connected to the cathode terminal of the power storage means by the anode wire,

More preferably, the cathode ray electrically connects the cathode terminal of the power supply means and the metal structure.

According to the present invention, by converting the kinetic energy of the wave into electrical energy and using it as a power source, it is possible to provide a self-generating electric system without using a battery.

Hereinafter, with reference to the drawings will be described a preferred embodiment of the present invention to provide specific details for the practice of the present invention.

3 is a schematic diagram of a self-powered electric system according to an embodiment of the present invention, FIG. 4 is a view for explaining an example of the power generation means shown in FIG. 3, FIG. 5 is shown in FIG. It is a figure for explaining another example of the said power generation means.

The self-generating electric system according to the present embodiment is to prevent corrosion of the metal structure for supporting the offshore structure, the power generation means 10, power storage means 20, the anode portion 30, the anode wire 40 And a cathode ray 50 and a float 60.

The power generation means 10 is to provide a power source for applying anticorrosive current to the metal structure (structure indicated by SS in FIG. 1), and focuses on using a metal structure for supporting the offshore structure. It is a configuration for generating power by converting kinetic energy into electrical energy.

The power generation means 10 is composed of a piezoelectric element 13 and the pressing means, the pressing means is composed of a spring 11 and the gravity body (12).

The spring 11 repeatedly causes the elastic deformation that the buoyancy body 60 is increased and decreased by the kinetic energy when the buoyancy body 60 moves up and down, and the weight body 12 provided at the end of the spring 11 is a piezoelectric element. Electric force is generated in the piezoelectric element 13 by hitting and pressing (13).

The piezoelectric element 13 is a device which converts mechanical energy into electrical energy or converts electrical energy into mechanical energy, as is well known.

Electrical energy generated by the power generation means 10 is transmitted to the power storage means 20 through the conductive wires (14, 15).

By this configuration, it is possible to self-generate without using a battery, the movement of the buoyancy body 60 by the wave is made continuously throughout the day regardless of the presence or absence of the sun or the weather, so the advantage of being able to develop all day There is this.

The electrical storage means 20 collects electrical energy generated by the power generating means 10 and is used as a power source for applying anticorrosive current.

Since the anode portion 30, the anode wire 40 and the cathode ray 50 are the same as those used in the conventional electric system, the detailed description thereof will be omitted.

The buoyancy body 60 is an annular structure as seen from above to surround the metal structure (SS) and the inside thereof, as shown in Figure 3, the power generation means 10, power storage means 20, the anode wire A portion of the 40 and a portion of the cathode ray 50 are accommodated therein, floating on the surface of the water, even if the surface fluctuates due to the movement of the wave or the tidal wave between the tidal portion 30 is always the electrolyte seawater It is configured to be immersed in the inside, and of course, even when the buoyancy body 60 moves in the vertical direction by the change of the surface, the cathode ray 50 is configured to be fixed to the metal structure (SS).

The driving mechanism of this embodiment is as follows.

First, when the buoyancy body 60 is moved up and down by the difference between the tidal wave or the wave, the spring 11 in the buoyancy body 60 is elastically deformed, and the gravity body 12 by the restoring force and inertia. ) Moves up and down to supply mechanical energy to the piezoelectric element 13. The supplied mechanical energy is converted into electrical energy in the piezoelectric element 13 and accumulated in the electrical storage means 20 through the conductive wires 14 and 15.

The electrical energy accumulated in the power storage means 20 is a power source to the method by the external power supply method.

Hereinafter, a self-generating electric system according to another embodiment of the present invention will be described.

Since the self-generating electricity type system according to the present embodiment differs only from the power generation means 110 and the rest of the configuration is the same as the previous embodiment, only the power generation means 110 will be described.

The power generation unit 110 of the present embodiment uses the law of induction current of Lenz, and is composed of a permanent magnet 112 and a coil 113 fixed to the spring 111 and the spring 111 to move together with the spring.

When the floating body moves up and down, the spring 111 repeats elastic deformation and restoration, and the permanent magnet 112 moves up and down along with the spring to change the magnetic field of the coil 113 to generate electric power from the coil 113. Is to use.

It is possible to generate power by such a configuration, and the generated electric energy is transferred to the power storage means through the wires 114 and 115, and the electric energy is accumulated in the power storage means, so that the power storage means becomes a power source and is operated by the external power method.

The configuration using the induced current may use the spring 111, the permanent magnet 112, and the coil 113 accommodated in the floating body as in the present embodiment, but install the coil inside the floating body without the spring. Permanent magnets can be installed on metal structures. In this case, the permanent magnet is fixed, and when the floating body moves up and down, the coil moves up and down to generate induced power. Although not shown, this configuration can be used as any means of power generation.

By describing the preferred embodiments of the present invention above it has been presented the specific content for the practice of the present invention. The technical spirit of the present invention is not limited to the described embodiments, and may be embodied in various forms of self-generating electric system within the spirit of the present invention.

1 is a view for explaining that the electric system is installed and used in the offshore structure.

Figure 2 is a schematic diagram of a conventional electrical system.

3 is a schematic diagram of a self-powered electric system according to an embodiment of the present invention.

4 is a view for explaining an example of the power generation means shown in FIG.

5 is a view for explaining another example of the power generation means shown in FIG. 3;

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

10: power generation means 20: power storage means

30: anode part 40: anode wire

50 cathode ray 60 floating body

Claims (5)

In the electric system of a metal structure installed at sea, Power generation means for applying anticorrosive current to the metal structure and installed in the metal structure to convert kinetic energy of seawater into electrical energy; An anode part for injecting anticorrosive current into the metal structure, the anode part being electrically connected to the anode terminal of the power generating means and the other end embedded in the surrounding sea water of the metal structure; A cathode wire connecting the anode terminal of the power generation means and the anode portion; A cathode wire connecting the cathode terminal of the power generation means and the metal structure; And, A float floating in the surface of the power generating means, a portion of the anode wire and a portion of the cathode ray provided therein and surrounding the outer circumference of the metal structure and allowing the other end of the anode wire to be embedded in sea water; Self-generating electric system characterized in that it comprises a. The method of claim 1, The power generation means, Self-powered electric system comprising a pressing means for pressing the piezoelectric element by the vertical movement of the piezoelectric element and the floating body. The method of claim 2, The pressing means, A spring provided inside the floating body and having one end fixed thereto; Self-powered electric system is installed on the other end of the spring and comprises a weight provided in a position capable of pressing the piezoelectric element. The method of claim 1, The power generation means, A spring provided inside the floating body and having one end fixed thereto; A permanent magnet installed at the other end of the spring, Self-powered electric system is characterized in that the permanent magnet is composed of a coil provided in a position that can generate an induced current when the movement of the floating body by the vertical movement. The method of claim 1, A power storage means accommodated in the floating body and accumulating electric power produced by the power generation means, The anode portion is electrically connected to the cathode terminal of the power storage means by the anode wire, The cathode ray is a self-powered electrical system, characterized in that for electrically connecting the cathode terminal of the power storage means and the metal structure.

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