KR20050010133A - Hybrid anode structure for cathodic protection - Google Patents

Abstract

PURPOSE: To provide a hybrid anode structure for cathodic protection which applies a core of consumable sacrificial anode to an insoluble anode material to sustain cathodic protection on an object without reconstruction of the anode through an impressed current type cathodic protection even after a consumable anode is consumed by sacrificial anode type cathodic protection. CONSTITUTION: In an anode structure applied to a metal structure in an electrolyte such as underground or underwater to perform cathodic protection, the hybrid anode structure for cathodic protection comprises a consumable sacrificial anode part(2) installed to proceed a sacrificial abode type cathodic protection; an insoluble anode part(1) applied to the consumable sacrificial anode part as a core to proceed an impressed current type cathodic protection; and an anode lead wire(3) for electrically connecting the insoluble anode part to a cathodic protection object, wherein the consumable sacrificial anode part surrounds the core of the insoluble anode part, wherein the consumable sacrificial anode part is formed of any one anode material selected from aluminum alloy anode, zinc alloy anode and magnesium alloy anode, wherein size and shape of the consumable sacrificial anode part are determined according to life of a desired anode, wherein the consumable sacrificial anode part is fabricated in a rectangular rod, semispherical or cylindrical shape, wherein the insoluble anode part is formed of any one insoluble anode material selected from high ferrosilicon anode, MMO anode and platinum-titanium anode, wherein size and shape of the insoluble anode part are determined according to life of a desired anode, and wherein the insoluble anode part is fabricated in a rod, tube, reticular or wire shape.

Description

HYBRID ANODE STRUCTURE FOR CATHODIC PROTECTION

The present invention relates to a hybrid anode structure for an electric method, and more particularly, by applying a core of a consumable sacrificial anode to an insoluble anode material, an external power-type electric method is used even after exhausting the exhausted anode by the sacrificial anode method. The present invention relates to a hybrid anode structure for an electrical method through which the method for an object can be continued without rebuilding the anode.

In general, corrosion means that metal (material) reacts with the surrounding environment and the metal itself is deteriorated or the properties of the metal are deteriorated. Such corrosion is mostly an electrochemical reaction (ie, a chemical reaction involving electron movement). ), And occurs when four elements, an anode, a cathode, a current path (metal path), and an ion path (electrolyte), are satisfied.

The combination consisting of the above four elements is called a corrosion cell, and when a corrosion cell is formed, the more active and lower potential metal of the two metals is anodized to corrode. The current flows along the cathode, current path, anode, and ion paths of the corroded cell, and the positive and negative reactions (oxidation reactions) and cathodic reactions (reduction reactions) occur as the current flows. In this case, corrosion occurs at the anode.

On the other hand, the corrosion of metal structures is caused by the anodic reaction and cathodic reaction by the corrosion mechanism in the state of the electrolyte such as soil or seawater. Inhibiting the progress of the reaction or separating the positive and negative parts in a third way is the basic method of preventing corrosion.

Since the first and third methods of the above methods cannot be a perfect method in reality, the method of suppressing the progress of the anode reaction, which is the second method, is the most widely used and is called the cathodic protection method. Corrosion of metal structures is a phenomenon that occurs when current flows out through the electrolyte from the metal surface. Therefore, the principle of the electric corrosion method is on the contrary. By dissipating the current) to prevent corrosion.

The electric method is largely divided into two types, the sacrificial anode method and the external power method, depending on the method of supplying the corrosion current. The sacrificial anode method is also called a dielectric anode method and is a method of obtaining a corrosion current by using a potential difference between dissimilar metals. Electrically connecting metals with a lower potential than the anticorrosive object (eg, aluminum, zinc, magnesium, etc.) in the electrolyte causes the metal with a lower potential to become an anode and the anticorrosive object becomes a cathode so that the anticorrosive current from the anode It is made to flow to an anode through an electrolyte.

In general, aluminum alloy anodes are mainly used for the submerged method of steel pipe piles for wharf facilities, which are one of marine structures, zinc alloy anodes are used for subsea piping, and magnesium alloy anodes are used for pipes buried in general soil.

The external power method is a method of connecting a positive electrode of a direct current power supply to a positive electrode provided in an electrolyte, connecting a negative electrode to an anticorrosive object, and then applying a power supply from the direct current power supply to flow the anticorrosive current. Say

This external power method consists of a DC power supply, an electrode bed, and an auxiliary wiring facility, and the anodes used are graphite, high silicon cast iron, and lead-silver (Pb-Ag). Made of materials such as alloys, precious metals and steel, there are insoluble anodes such as high silicon iron anodes, soft-silver alloy anodes and platinum-titanium (Pt-Ti (Nb / Ta / MMO)) anodes. Generally, anti-silver anode and platinum-titanium anode are used for anticorrosive objects installed in seawater, and high silicon iron anodes are used for anticorrosive objects installed in seawater.

Comparing the advantages and disadvantages of the sacrificial anode method and the external power method applied to the electric method is shown in Table 1 below.

Anticorrosion Advantages Disadvantages Sacrificial bipolarization No external power is required 2. Easy to install and easy to maintain 3. The cost of small structures is low. There is little effect of interference on other facilities. 5. The distribution of anticorrosive potential is relatively uniform, and there is no fear of overeating. The installation area of anticorrosive equipment can be minimized. Anticorrosive current can be used effectively. The electromotive force of the anode is limited, and the output current is small, so it is expensive for the long-distance object. Anticorrosion effect range is narrow 3. It is difficult to control the output of voltage and current. 4. Inefficient installation in places with high specific resistance. 5. The cost per unit current is higher than the external power method. 6. It is not effective in strong eating. External power law Wide range of adjustment of voltage and current, economical for long distance type objects 2. Large current output even with one anode 3. Wide range of anticorrosive effect 4. It can be applied even in places with high specific resistance. It also works for meals. 6. Due to the small consumption of the anode, the cost per unit current is smaller than that of the sacrificial anode type. It is easy to influence interference with other facilities. 2. In case of loss of external power, the system is in a beautiful state. 3. Periodic maintenance and repair is required. 4. An external power source is required. 5. There is a risk of overeating 6. Maintenance costs such as power bills are relatively expensive. The cost of small structures is expensive.

On the other hand, conventionally, the electric method is generally performed by the sacrificial anode method using the consumable sacrificial anode, the electric method is generally performed by the external power method using the insoluble anode, or simply the two methods are applied in parallel. It was a form.

However, with the rapid progress of urbanization and industrialization, the utilization of metal facilities installed in electrolytes such as underground or water is increasing rapidly, and as various facilities owned by other institutions are complicatedly distributed, The electrical method for this requires a new solution. That is, the sacrificial anode method, which has been used in the method of relatively small structures, has little interference effect on other facilities, while the risk of having to reconstruct on the road or railway on the ground when maintenance is required or the life of the consumable sacrificial anode is over. Inconvenience and high cost are required, and road reconstruction in places with heavy traffic, such as urban areas, is becoming increasingly difficult due to the negative effects on the lives of urban residents.

In addition, the external power method is more effective than the sacrificial anode method in terms of effect, economics, and constructability, but the current situation is reducing the application of the external power method worldwide as the problem of interference with other facilities becomes serious.

Therefore, in recent years, there is an urgent need for the development of new technologies and materials that can make use of the technical complementary to the sacrificial anode method which is recommended as the electric method for underground or underwater metal facilities and the electric method.

Accordingly, the present invention has been made in view of the above-mentioned conventional circumstances, and an object thereof is to use an insoluble anode used as a core even after the consumable sacrificial anode has reached the end of its life by using a hybrid anode for the electric method during the sacrificial anode type electric construction. It is to provide a hybrid anode structure for the electrical method to enable the electrical method.

1 is a view showing in detail the structure of the hybrid anode for an electric system according to the present invention.

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

1: insoluble anode, 2: consumable sacrificial anode,

3: anode lead wire.

In order to achieve the above object, according to the present invention, in the anode structure applied to the metal facilities in the electrolyte, such as underground or underwater to perform the electrical system, a sacrificial anode positive electrode portion installed so that the sacrificial anode electrical system, and the A hybrid anode structure for an electrical method, comprising: an insoluble anode part applied as a core to a consumable sacrificial anode part and installed to perform an external power-type electric method; and an anode lead wire for electrically connecting the insoluble anode part to a method object. To provide.

Hereinafter, the present invention configured as described above will be described in detail with reference to the accompanying drawings.

That is, Figure 1 is a view showing in detail the structure of the hybrid anode for electric method according to the present invention.

As shown in FIG. 1, the hybrid anode structure for an electric system according to the present invention includes an insoluble anode portion 1, a consumable sacrificial anode portion 2, and an anode lead wire 3.

The insoluble anode portion 1 is composed of a high silicon iron anode, MMO anode, platinum-titanium anode constituting the core, the size and shape of the insoluble anode portion 1 is determined according to the life of the desired anode, rod shape, It can be produced in various forms such as tube shape, mesh shape, wire shape, etc. The insoluble anode part 1 uses an insoluble anode material used for an external power-type electric method such as a high silicon iron anode, an MMO anode, a platinum-titanium anode, etc. according to the surrounding environment of the anticorrosive object.

The consumable sacrificial anode part 2 is composed of an aluminum alloy anode, a zinc alloy anode, and a magnesium alloy anode surrounding the core, and the size and shape of the consumable sacrificial anode part 2 are determined according to the life of the desired anode, and each rod The shape, hemispherical shape, cylindrical shape and the like can be produced in various forms. The insoluble anode portion 2 uses a consumable sacrificial anode material used in a sacrificial anode electrical method, such as aluminum alloy anode, zinc alloy anode, magnesium alloy anode, etc. according to the surrounding environment of the anticorrosive object.

The anode lead wire 3 is connected to one end of the insoluble anode part 1 and is configured to be drawn out to a test box on the ground. The anode lead wire 3 preferably uses a rigid wire made of an insulating material. .

The hybrid anode according to the present invention is manufactured so that the insoluble anode portion 10 can be used in the core, the anode lead wires 3 are connected at both ends or one end thereof, and then the consumable sacrificial anode portion 2 is added to the outside thereof. Manufactured by casting to cover.

The life of the hybrid anode is calculated by the life of the consumable sacrificial anode 2 and the insoluble anode 1, the life of the consumable sacrificial anode 2 is obtained by the following equation (1).

Here, Y ₁ is the lifetime [y] of the consumable sacrificial anode portion 2, C _a1 is the current capacity [A · y / kg] of the consumable sacrificial anode portion 2, W _t1 is the The weight [kg], f ₁ represents the utilization rate of the consumable sacrificial anode portion 2, and I _t1 represents the output current [A] of the anode.

In addition, the lifetime of the insoluble anode part 1 is calculated | required by following formula (2).

Where Y ₂ is the lifetime [y] of the insoluble anode portion 1, W _t2 is the weight [kg] of the insoluble anode portion 1, f ₂ is the utilization rate of the insoluble anode portion 1, and I _t2 is the insoluble anode portion. The output current [A] and C _r2 in (1) represent the consumption rate [kg / A · y] of the insoluble anode portion 1.

In the present invention configured as described above, it is possible to extend the life of the anode by the life (Y ₂ ) of the insoluble anode part 1 without the life of the conventional sacrificial anode type electrochemical method and additional anode installation cost.

On the other hand, the present invention is not limited to the above-described typical preferred embodiments, but can be carried out in various ways without departing from the gist of the present invention, various modifications, alterations, substitutions or additions are common in the art Those who have knowledge will easily understand. If the implementation by such improvement, change, replacement or addition falls within the scope of the appended claims, the technical idea should also be regarded as belonging to the present invention.

As described above, according to the present invention, by using the hybrid anode for the electrical method in place of the consumable sacrificial anode during the electrical method construction, the first method using the sacrificial anode, and if the sacrificial anode is exhausted, there is no additional anode installation cost By using the external power supply anode, which is a core, it has the effect of continuously implementing the method for the metal structure without the need for reconstruction at an additional cost.

Claims (8)

In the anode structure which is applied to metal facilities in the electrolyte such as underground or underwater to perform the electrical method, A consumable sacrificial anode which is installed so that the sacrificial bipolar electric system proceeds; An insoluble anode portion applied as a core to the consumable sacrificial anode portion and installed to proceed with an externally powered electric system; And an anode lead wire for electrically connecting the insoluble anode portion to an anticorrosive object. The method of claim 1, And the consumable sacrificial anode portion is formed surrounding the core of the insoluble anode portion. The method of claim 1, The consumable sacrificial anode portion is an electrical alloy hybrid anode structure, characterized in that made of any one anode material of the aluminum alloy anode, zinc alloy anode, magnesium alloy anode. The method of claim 1, The size and shape of the consumable sacrificial anode portion is determined according to the life of the desired anode hybrid anode structure for the electrical method. The method of claim 4, wherein The consumable sacrificial anode portion is an electric hybrid hybrid anode structure, characterized in that the production of any one of a rod-shaped, hemispherical, cylindrical shape. The method of claim 1, The insoluble anode portion is a high-silicon iron anode, MMO anode, platinum-titanium anode of any one of the insoluble anode material, characterized in that the hybrid anode structure for electric. The method of claim 1, The size and shape of the insoluble anode portion is determined according to the life of the desired anode hybrid anode structure for the electric method. The method of claim 7, wherein The insoluble anode portion is a hybrid anode structure for an electric system, characterized in that the rod, tube, mesh, wire shape is produced in any one form.