DE2916934C2 - Method and device for maintaining cathodic protection against corrosion - Google Patents

Abstract

1. A method of maintaining cathodic corrosion protection for metal surface which are in contact with an electrolyte, with external current, using an inert electrode as the external current anode and a potentiostat, characterised in that periodically the protective current is switched off and a measurement is taken of the potential (Eist ) directly between the external current anode which in this phase operates as a reference electrode, and the surface to be protected, and the potential (Eist ) is compared to the protective potential (E soll ) which is set at the potentiostat, and the difference (E ist - E soll ) is used directly as a control value in respect of the protective current.

Description

The invention is directed to a method and apparatus for maintaining a cathodic Corrosion protection for metallic surfaces with external current that are in contact with an electrolyte, using an inert electrode as an impressed current anode and a potentiostat.

In order to achieve optimal corrosion protection, a large number of possibilities are already known: the simplest and long-known possibility in the use of so-called Sacrificial anodes consists of a metal that is much less noble than the metal to be protected and are short-circuited together with this, so that in connection with the electrolyte a galvanic Element arises from which a certain protective current can be generated. An improved corrosion protection leaves can be achieved by applying an external current. In order to make changes to the object to be protected It is known to be able to detect the protective potential by means of a reference electrode measure and keep constant with the help of a potentiostat.

In such measurements, however, due to the electric field and a finite distance, the Reference electrode from the wall to be protected, the so-called resistance polarization or the IR component is also measured, which leads to falsifications can lead to the effectiveness of the cathodic corrosion protection, depending on the area of application, in question can ask.

To suppress this resistance polarization is the inventor in a not yet published Application has been proposed, the reference electrode, to put it simply, with a kind of Faraday Shield the cage so that continuous IR-free measurement is possible

This known type of measurement with a shielded reference electrode and control with a Potentiostat enables very good protection against corrosion, but it is still a reference electrode used, which represents the most sensitive component in the overall system, with the shortest service life and the greatest susceptibility to failure

The object of the invention is to create a solution with which a very good measurement of the Protection potential on the one hand and on the other hand an optimal regulation of the protective current is possible, wherein a failure-prone reference electrode is completely avoided.

This object is achieved with a method of the type specified in the introduction according to the invention solved in that the protective current switches off periodically and the existing potential directly between the external current anode, which acts as a reference electrode in this phase, and the one to be protected Surface is measured and compared with the protective potential set on the potentiostat and the Difference is used directly as a control variable for the protective current.

The procedure according to the invention completely avoids a reference electrode. This is possible because the inert ones used here. Electrodes through the evolution of oxygen during the polarization that occupies the surface, this oxygen occupancy after switching off of the protective current is maintained for a certain time, a characteristic potential in this state exhibit. This potential corresponds to that of an oxygen electrode, so that with the help of this an exact measurement is possible with the defined potential. This shutdown measurement also shows that by the immediate disappearance of the disruptive ohmic voltage drop after switching off the IR-free potential is measured.

The intermittent disconnection of the protective current is harmless for the corrosion protection itself, because here on the surfaces to be protected by pre-polarization, the protection potential also lags a certain time after switching off remains, since the processes responsible for the corrosion are comparative run sluggishly. In an embodiment, the invention provides that during the protective current switch-off phase Control deviation integrated several times and the integrated voltage reduces the protective current during the controls the following protective current phase. This configuration makes it possible to reduce the protective current very much precisely set and to keep constant, whereby due to a further feature of the invention, which consists in the fact that the protective current switch-off phase is many times smaller than the protective current phase

that is attainable is that the benefits of a practically constant protective current application can be maintained on the surface to be protected.

In a further embodiment it is provided according to the invention that the protective current phase is in the range approximately half a millisecond is what we're talking about here standing electrochemical processes means that the protective potential is always maintained.

Due to the procedure according to the invention, changes in the state in the system can be compensated very quickly, so optimal corrosion protection can be achieved is

A device for carrying out the method according to the invention is distinguished according to the invention through a power supply unit with transformer and rectifier, a setpoint voltage generator for setting the Protection potential, an isolating amplifier and electronic double switch with control element as well as a integrator and a current amplifier, the elements in circuit connection with the to protective surface and a dual function as an impressed current anode and reference electrode Electrode stand.

The invention is explained in more detail below with reference to the drawing, for example. This shows in F i g. 1 is a circuit diagram of a device,

F i g. 2 shows a voltage / time diagram and in

F i g. 3 is a current / time diagram.

As can be seen from FIG. 1 results, the surface 1 to be protected is in contact with an electrolyte 2, for example sea water in a ship's hull or household water in a hot water boiler or the like. The surface 1 to be protected is connected to a nominal voltage transmitter 3, with which the protection _potential £ i0 /; can be adjusted.

Via line 4, the nominal voltage generator 3 is connected to an isolating amplifier 5, one of which Output 6 acts on one part 7 of a double switch 8. The other part of the double switch 8 is denoted by 9. An integrator 10 is located between the two parts 7 and 9 of the double switch 8.

The double switch 8 is, as can be seen from FIG. 1 results, operated by a control element 11, which once includes a timer and performs the "on / off" functions. Behind the part 9 of the double switch 8 is a Current amplifier 12 switched, one output of which is connected via line 13 to one in the electrolyte 2 immersing electrode 14 is connected. The electrode 14 in turn is also via a line 15 with the Isolation amplifier 5 connected.

The system receives the energy required to regulate and maintain the protective potential by a hinted power supply 16, its inputs and outputs with the corresponding Voltage designations that correspond to those of the inputs and outputs of the protection system are.

The operation of the device according to the invention is as follows: During the potential interval determined by the control element 11, the transistor 7 serving as a current amplifier is decoupled by the switch 8 and the potential F, "between the electrode 14 acting as a reference electrode in this switching state and the one to be protected Surface 1 compared, with the surface to be protected lying on ground. Any control deviation (E, _s , - Es ₀ Ii) that may be present is integrated several times by the integrator 10 in the potential interval, in each case in a time period that is significantly smaller than the potential interval itself. This integrated voltage controls the control element 11 certain current interval the protective current that flows between the electrode 14, which acts as an external current anode in this phase, and the surface 1 to be protected.

This process is repeated periodically. In the event of a control deviation, the protective current is set accordingly changed, if the control deviation is zero, the protective current remains constant.

In the F i g. 2 and 3 are the results of an experiment with a device according to the invention plotted. An electrode made of platinum-coated titanium was used for the experiment; the surface to be protected was that of an iron object. Water with a conductivity of 110 μβ cm- 'was used as the electrolyte. In this experiment, a nominal voltage Esoii = 2300 mV was set between the electrode and the iron. During the experiment, the potential interval lasted approx. 40 \ is. The current interval lasted 400 μβ. The difference between the potential values in the current and potential integral resulting from the figures corresponds to the ohmic voltage drop which, in the case of the experiment, resulted in Δ LJ = 200 mV.

The piece of iron used in the experiment showed no traces of, even after a long period of time Corrosion.

All surfaces subject to corrosion can be used as the surface to be protected. are only temporarily exposed to electrolytes, for example metal roofs in rain or snow, Pipes exposed to seawater, groundwater or other waters, hot water boilers, Storage boiler or the like.

For this purpose 3 sheets of drawings

Claims (5)

Patent claims: 1. A method for maintaining a cathodic corrosion protection for metallic surfaces in contact with an electrolyte, with external current using an inert electrode as external current anode and a potentiostat, characterized in that the protective current is switched off periodically and the existing potential (Eu,) directly between the external current anode acting as a reference electrode in this phase and the surface to be protected is measured and compared with the protective potential (E _so ii) set on the potentiostat and the difference (Ei ₅₁ - E _so ii) is used directly as a control variable for the protective current. 2. The method according to claim 1, characterized in that during the protective current shutdown phase a control deviation is integrated several times and the integrated voltage the protective current controls during the following protective current phase. 3. The method according to claims 1 or 2, characterized in that the protective current switch-off phase is kept many times smaller than the protective current phase. 4. The method according to any one of the preceding claims, characterized in that the protective current phase is held in the range of about half a millisecond. 5. Device for performing the method according to claims 1 to 4, characterized by a power supply unit (16) with transformer and rectifier, a nominal voltage generator (3) for setting the protective potential (E _so n), an isolating amplifier (5) and electronic double switch ( 8) with control element (U) as well as an integrator (10) and a current amplifier (12), the elements being in circuit connection with the surface to be protected (1) and an electrode (14) that performs the double function of an external current anode and reference electrode.