FI100193B - electrode design - Google Patents

Description

5 100193

The electrode structure

electrode structure

The invention relates to an electrode structure, in particular an anode structure for cathodic corrosion protection used in concrete structures, comprising an anode placed in the concrete structure and a power supply part for supplying direct current to the anode.

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Cathodic protection is old as an invention, but its application in practice has been limited until recent decades due to material technology. Cathodic protection can be implemented in two different ways: using an external power supply technique or a galvanic pair, i.e. the principle of a 15 sacrificial anode.

Cathodic shielding typically has three main components, namely an anode, i.e. an electrode that supplies current, a cathode, i.e. a metal structure to be protected, which receives current, and an electrolyte, i.e. a conductor 20, between the anode and the cathode. In an external power supply system, the system includes, in addition to the above, a DC power supply, a reference electrode for indicating the amount of current required, and a control unit for collecting and storing data and adjusting the protection system.

25: The principle of cathodic protection is to move the structure to be protected • 2 100193 from the thickness of the concrete shell and the operating environment. 2) The chloride content of the components used in the production of concrete mass and the absorption of salts in the environment of use, mainly chlorides, through the concrete protective layer. Corrosion causes the volume-5 of rebar to multiply, which in turn breaks the concrete that protects it. Corrosion accelerates with the breakage of the concrete and eventually the strength properties of the structure no longer meet the requirements set for it.

For the reasons mentioned above, the economic losses to society caused by corrosion are large.

The expansion of the use of cathodic shielding has largely depended on the anode material and construction. Current anode solutions are: 1) reticulated anode, 2) strip-like so-called grid anode, 3) pin anode, 4 4) anode paints, 5) thermally sprayable metals and 6) electrically conductive masses.

In the cathodic corrosion protection of concrete structures, a reticulated anode structure has been used as the anode, as disclosed, for example, in EP Patent No. 0222829 20. The so-called anode has also been used. Grid-type anode or tee; wire-anode. Furthermore, pin anodes and anode paint have been used as the anode.

When a reticulated anode according to EP patent no. 0222829 is used, the conductor is shotcrete. The disadvantage of this known solution is e.g.

•% • · · t the fact that shotcrete is easily laminated away from the concrete structure. This • · · ·. · · Solution is mainly suitable for large flat surfaces, but the solution increases the mass of the concrete structure. Furthermore, in this known solution, the • short-circuit risk is high. In addition, the shotcrete surface * · · · 30 does not always meet the criteria set for facades. 1

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When using a grid-type anode or a wire anode, the conductor is a concrete mass. This solution is relatively difficult to install because the solution requires a deep groove. In this solution in particular, the risk of a short circuit is considerably high.

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When a pin anode is used, the conductor is an electrically conductive mass. The pin anode is relatively easy to install and there is no short circuit risk. Using a pin anode makes it much easier to treat local areas of corrosion. In addition, the current conductivity of the pin anode is relatively good.

When using anodic paint, the solution requires joints, which makes the solution relatively uncertain. The disadvantage of this solution is also the poor and uneven current conductivity. In addition, this solution cannot be used in all applications, such as the facades of bridges or other structures. The life of the anode paint is the most limited of the electrode solutions presented above.

It is an object of the invention to provide an improvement over the currently known electrode structures.

It is a more detailed object of the invention to provide an electrode structure which, for example when used as an anode structure, works as well as a pin anode solution, and which in addition achieves some advantages over a conventional pin anode solution.

The objects of the invention are achieved by an electrode structure characterized in that a resistor is integrated in the anode structure, which is connected at one end to the power supply part and at the other end to the anode.

i.i 25 • · • · ·: The electrode structure according to the invention achieves a number of significant advantages. The electrode structure according to the invention is suitable for use as an anode in all kinds of applications of cathodic corrosion protection, such as in various concrete structures. The invention has realized • · · ·. * J *. 30 to integrate a resistor into the electrode structure, allowing for different applications ’. if necessary, a different resistance value can be used, usually preferably between 5 ... 10,000 Ω. This has the significant advantage that several anodes, e.g. 2 ... 200, usually 20 ... 50, can be sensibly connected in series with each other and different resistor values can be used in different anodes, whereby the cathodic protection can be implemented in different applications in the most meaningful and efficient way possible. As the pin material of the electrode structure 4 100193 according to the invention, materials known per se, such as, for example, platinum-plated titanium or various alloyed metal oxide coatings, can be used.

The anode-integrated resistor according to the invention further offers the following advantages: the installation of the electrode is easier, the amount of connection cable required is considerably lower, especially in façades it is cleaner and less noticeable, the anodes are more serviceable and the installation costs are lower.

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The invention will be explained in detail with reference to a preferred embodiment of the invention shown in the figures of the accompanying drawings, to which, however, the invention is not intended to be exclusively limited.

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Figure 1 shows a schematic cross-section of a preferred embodiment of an electrode structure according to the invention.

Figure 2 shows a schematic side view of an embodiment of an electrode structure according to the invention.

, Figure 3 shows a schematic side view of another embodiment of the electrode structure according to the invention.

In the embodiments according to Figures 1-3, the electro-structure according to the invention, in this case the anode structure, is denoted by reference numeral 10. The anode structure 10 comprises an anode pin 11 which is placed in a mounting hole 12 in the concrete structure 13.

«The outer surface of the concrete structure 13 is denoted by reference numeral 13a. As shown in Figures 2 and 3, the anode pin 11 is surrounded by an anode mass 14.

The power supply portion of the anode structure 10 is generally indicated by reference numeral 15 and the associated power supply conductor by reference numeral 16. The power supply portion 15 also includes a nut or the like, preferably a titanium-35 nut 17.

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As shown in Figure 1, in accordance with the basic understanding of the invention, a resistor 18 is integrated in the anode structure 10. A resistor 18 is attached between the anode pin 11 and the power supply part 15. Resistor 18 may communicate at one end with an anode pin 11 and at its other end with a spring device 5 (not shown), the spring device being attached to the power supply portion 15. Resistor 18 may equally communicate at one end with the power supply portion 15 and at the other end with a spring device (not shown). wherein the spring device is in turn attached to the anode pin 11.

The resistor 18 and the possible spring device are located in the oil space 20, whereby 10 possible rusting of the spring device, for example, is avoided. Reference numeral 21 denotes a sealing mass and reference numeral 22 denotes a seal surrounding the anode structure according to the invention, starting from the power supply part 15 and ending at the anode pin 11.

In the embodiment according to Figure 2, the anode structure according to the invention has been adapted for use in the cathodic corrosion protection of a concrete structure 13 as a horizontal installation.

In the embodiment according to Figure 3, the anode structure 20 according to the invention is correspondingly applied as a vertical installation. In the embodiment of Figure 3, the titanium nut 17 and the power supply conductor 16 are preferably. covered with plastic sealing tape 23.

Only the basic solution of the invention and its two practical application examples have been presented above. It will be apparent to those skilled in the art that numerous modifications may be made thereto within the scope of the inventive idea set forth in the appended claims.

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Claims (7)

100193 An electrode structure, in particular an anode structure (10) for cathodic corrosion protection used in concrete structures (13), comprising an anode (11) 5 placed in the concrete structure (13) and a power supply section (15) for supplying direct current to the anode (11), characterized in (10) is an integrated resistor (18) which communicates at one end with the power supply section (15) and at the other end with the anode (11). 10 Electrode structure according to Claim 1, characterized in that the resistor (18) and the possible spring device are located in the oil space (20). Electrode structure according to Claim 1 or 2, characterized in that the power supply part (15) comprises a power supply line (16) and a fastener (17). Electrode structure according to one of Claims 1 to 3, characterized in that the unitary seal (22) at least partially surrounds the current supply part (15) and the anode pin (11). i Electrode structure according to one of Claims 1 to 3, characterized in that the anode mass (14) is arranged around the anode pin (11). • * f ♦ · * * · * ·· · ♦ ·· Electrode structure according to one of Claims 1 to 5, characterized in that the magnitude of the resistor (18) is between 5 and 10,000 Ω. • ♦ • · · ♦ · · «* · · • 30 Electrode structure according to one of Claims 1 to 6, characterized in that the power supply part (15) is covered with a plastic sealing strip (23). • ψ · «· 100193