CH708614A2 - A method for locating steel surfaces in contact with an electrolyte and for determining the state of corrosion. - Google Patents

Abstract

A method for locating steel surfaces 1 which are in contact with an electrolyte 3 and for determining their corrosion state is presented. One or more devices 7 by current flow between the steel structure 2 and an electrode 10, the potentials E0 to EX for the duration t0 to tX on the steel structure 2 on. The currents I0 to IX passing through the steel surface 1 are detected as voltages U0 to UX between a first reference electrode 4 and a second reference electrode 5 with a voltmeter 6. The corrosion state is evaluated by analyzing the dependence of the voltages (U0) to (UX) on the potentials (E0) to (EX) and evaluating the time course of the absolute value of the voltage EX as a function of time. By carrying out the measurement along a large steel structure 2, it is possible to draw conclusions about the distribution and the position of steel surfaces 1 and their state of corrosion.

Description

Description Technical area

The invention relates to a method for locating steel surfaces, which are in contact with an electrolyte, and for determining their corrosion state.

State of the art

Steel transport pipes are protected from corrosion by a high quality outer sheath and a cathodic corrosion protection (KKS). The effectiveness of the KKS comes here in defects of the outer sheath of the pipeline to bear, since there is the steel surface in contact with an electrolyte. The entry of the protective current into the steel surface consumes the oxygen in the surrounding soil and raises the pH at the steel surface. Recent findings show that the effectiveness of the KKS in most cases is based on the formation of the passive film, which can form due to the increase in the pH of the steel surface. Typically, these conditions of passivity are met when the potential of the steel surface, the so-called IR-free potential, is more negative than -0.85 V measured against a copper / saturated copper sulfate electrode (CSE). However, recent studies have shown that significantly more positive potentials do not necessarily lead to corrosion. This is true in cases where the pH on the steel surface is sufficiently high and the settings of the KKS, the high-resistance well-ventilated soil or the large steel surface prevent the potential from dropping. This circumstance is taken into account in EN 12 954, in that under certain conditions also more positive IR-free potentials of -0.75 and -0.65 V CSE are permissible. The problem now is that even a steel surface without effective KKS and thus insufficient increase in the pH at the steel surface can have IR-free potentials in this area. Thus, the measurement of the IR-free potential does not always allow the reliable proof of the effectiveness of the KKS.

There are conditions of flaw surfaces under which the pH can not increase, for example, due to flowing water or in the presence of sulfate-reducing bacteria. Under these conditions, the IR-free potential must be more negative than -0.95 V CSE to ensure corrosion protection due to the immunity of the steel surface. All these empirical values are anchored in the current EN 12 954. With the help of kinetic and thermodynamic considerations, it is possible to explain these limit values of EN 12 954 as well as the mode of action of the KKS. It is clear from the discussion that a final assessment of the effectiveness of the PPS is only possible if the IR-free potential is more negative than -0.95 V CSE. Under these conditions, protection is guaranteed either by immunity or passivity. For all other limit values of EN 12 954, it must be ensured that the pH at the steel surface is sufficiently high to allow the formation of the protective passive film.

So far, this was not a problem because the cathodic corrosion protection was set so negative that on all steel surfaces in the defects of the envelope an IR-free potential was more negative than -0.95 V CSE reached. Proof of compliance with this potential was provided by means of the so-called intensive measurement according to EN 13 509. This method is based on the simultaneous measurement of the pipeline potential and the voltage funnel above the pipeline with cycled protection current. This means that the protective current devices along the pipeline were switched on at predetermined intervals (for example 12 seconds on, 3 seconds off) and a measuring group consisting of two persons followed the line and detected the potential and the voltage junction between two reference electrodes (mostly CSE). With the aid of the measurement, both larger imperfections in the cladding are identified and their IR-free potential recorded.

The problem of this method is that a measuring contact must be made to the line for the measurement of the pipeline potential. Usually these measuring contacts are available every 1000 to 2000 m at the pipeline. The metrological effort is significant, since a measuring cable of appropriate length must be carried along.

Another problem is that with this approach, small imperfections in the enclosure due to the low voltage funnel can not be identified. In the so-called Intensive Fault Location (IFO), the potential is set strongly negative (e.g., -20V CSE), resulting in significantly larger voltage straighteners and thus improved location of cladding defects. Since in this case only the voltage funnel is measured between two electrodes with clocked protection current, the metrological effort is significantly lower. This process is also referred to as DCVG. The disadvantage is that this method makes no statement regarding the effectiveness of the cathodic corrosion protection, since no conclusions about the IR-free potential or the corrosion state of the located defects is possible and that the corrosion state of the line is strongly changed at negative potentials.

Based on these statements, it is clear that both an established method for the detection of the effectiveness of the KKS and methods for the detection of defects exist. However, there are two main problems that make the application of these two methods difficult:

- In older pipelines, the enclosure is partially in such a poor condition that IR-free potentials more negative than -0.95 V CSE can not be achieved with technically reasonable effort.

2 - For new pipelines, to reduce the risk of AC corrosion, the potential must be set so positively that the IR-free potentials are significantly more positive than -0.95 V CSE. This should not be confused with inadequate corrosion protection, since the increase of the pH value and the passive film that forms are normally effective in preventing corrosion. A proof of the effectiveness with the help of the IR-free potential is no longer possible. In addition, the remaining stress funnels at the defects can hardly be detected metrologically. By lowering the potential, an IFO can be carried out, but the risk of AC corrosion is greatly increased.

Because of these statements, it is clear that under the current conditions with strong AC interference and very poor quality wrapping the previous requirements of an IR-free potential negative than -0.95 V CSE can no longer be met.

Specifically, there is a need for a method which allows the lowest possible metrological effort locating defects, the determination of the IR-free potential and the detection of passivity. This would have to enable the comprehensive proof of the effectiveness of the KKS under the described boundary conditions.

Presentation of the invention

The invention has for its object to locate steel surfaces on steel structures and to determine the corrosion state.

This is achieved by the characterizing features of the first claim according to the invention.

The essence of the invention is that the location of steel surfaces, which are in contact with an electrolyte, and the determination of the corrosion state by the application of different potentials on the pipeline and the detection of the occurring due to the passage of current through the steel surface takes place in the electrolyte forming voltage funnel.

The advantage of the invention is that in one measurement, both the location of the steel surface, the determination of the corrosion state and the proof of the effectiveness of the KKS are possible. The measurement effort compared to existing methods is significantly reduced, since no measuring contact to the line is required and the negative effects of a strong cathodic polarization are compensated for the AC corrosion.

The measurement setup corresponds in principle to that of an IFO. This means that the voltage funnels above the pipeline are detected between two reference electrodes, whereby the first reference electrode is positioned laterally offset in the vicinity or directly above the pipeline and the second reference electrode. With a small number of defects it is sufficient to position both reference electrodes above the pipeline. The key difference is that the protection current to the line is not simply interrupted and turned back on, but that a sequence of predetermined potentials is set via a current flow between an electrode and the covered pipe, for example an anode system. This sequence consists, for example, of the following phases: a) 1 second (t1) at -0.95 V CSE (E1) b) 3 seconds (t2) at 0 V CSE (E2) c) 2 seconds (t3) at -3 V CSE (E3 ) d) 10 seconds (to) at the usual potential of eg -1.17 V CSE (EO)

By detecting the voltage funnels and their time course, the following statements are possible:

- Phase a): From the sign of the voltage (U1) between the two reference electrodes can be concluded whether the IR-free potential is more positive or negative than -0.95 V CSE.

- Phase b): From the magnitude of the voltage (U2) a statement is possible whether passivity is present or not. The time course of the voltage (U2) can further confirm this conclusion.

- Phase c): The negative potential (E3) leads to increased voltages (U3) and allows the detection of even the smallest defects. In addition, the evaluation of the voltage (U2) in phase b) is possible.

- Phase d): The defects can return to a stable normal operating condition.

Since the time average of the negative and positive potential shifts that in phase d) corresponds to the negative effects of anodic and cathodic influences can be eliminated according to the latest knowledge or at least greatly reduced.

Thus, with the same proven measuring principle, a comprehensive assessment of the position of the steel surfaces on the covered pipe, the effectiveness of the KKS and the corrosion state can be made, in contrast to the intensive measurement no potential connection must be pulled to the pipeline. So that the effect of the longitudinal voltage drop on the pipeline can be detected and taken into account, the potential of the four states against a remote reference electrode must be checked and, if necessary, adjusted for each measuring contact. The adjustment can be done manually, remotely or fully automatically in real time. For the latter, a remote monitoring with data connection to the protective current devices must be available at the measuring contact. Alternatively, the effective value of the potential may also be recorded, with the measurement data being later compared with the actual values present.

3 Brief description of the drawings [0018]

In Fig. 1, the measurement setup for the location of steel surfaces 1, which are in contact with the surrounding electrolyte 3, shown on a coated steel structure 2 and for determining their corrosion state.

FIG. 2 shows the voltages U0 to U3 measured at different potentials E0 to E3 of the steel structure for different steel surfaces 1 A, B, C and D, which are in contact with the electrolyte 3

FIG. 3 shows the time profile of the voltage U2 at the potential E2 for a steel surface 1A in contact with an electrolyte 3 with a neutral phl value and a steel surface 1B in contact with an electrolyte 3 with a phl value of 13 ,

FIG. 4 shows the measuring setup on a measuring contact 11 in the vicinity of the first reference electrode 4, which is used for the adaptation or regulation respectively registration of the potentials E0 to E3.

In Fig. 5, the structure of the grounding systems 15 is shown with capacitors 14, which allows a quick switching of the potentials E0 to E3.

Way to carry out the invention

Fig. 1 shows the basic measurement setup for the location of a steel surface 1, which is in contact with an electrolyte 3, and for the detection of the corrosion state of a steel structure 2, which is preferably enveloped. The currents 10 to 13, which at the potentials E0 to E3 pass through the steel surface 1 into the electrolyte 3, are referred to as voltages U0 to U3 between a first reference electrode 4 and a second reference electrode 5 with the aid of a voltage measuring device 6 at different potentials E0 to E3 measured. The potentials E0 to E3 are set by means of an electric current between an electrode 10 and the steel structure 2 of a device 7. The first reference electrode 4 is brought into contact with the electrolyte 3 via the steel structure 2, while the second reference electrode 5 is brought into contact laterally offset from the steel structure 2 with the electrolyte 3. The device 7 is capable of applying the potentials E0 to E3 cyclically to the steel structure 2 during the times t0 to t3. The protective current device 7 can apply the various potentials, for example with the aid of a changeover switch 8 and a plurality of DC voltage sources 9, to the steel structure 2 via an electrode 10. Alternatively, the device 7 can also set the potentials by means of pulse modulation, via operational amplifier or potential control.

By moving the first reference electrode 4 along the steel structure 2, it is possible to detect the lateral distribution of the voltages UO to U3. The second reference electrode 5 may be stationary or also be moved.

In Fig. 2, the results of measurement on four steel surfaces 1 A, B, C and D are shown. The polarization periods t1 to t3 were chosen so that the time average of the potential was more negative than -1 V and preferably in the range of EO. Thus, an influence on the steel structure during the measurement could be minimized. In these measurements, the first reference electrode 4 has been connected to the "com" terminal of the voltmeter 6. At E3 of -3 V CSE and EO of -1.17 V CSE clear stress chutes were found in all four cases, which are a consequence of the current access to the steel surfaces 1. At E1 of -0.95 V CSE, a positive voltage U1 is found at A and B. This means that the IR-free potential of the steel surfaces 1 is more positive than -0.95 V CSE. An assessment of the effectiveness of the KKS is therefore not possible for A and B based on E1. In contrast, in the steel surfaces 1 C and D, a slightly negative voltage U1 is measured. This means that the IR-free potential at steel surface 1 C and D is more negative than the criterion of -0.95 V CSE. Consequently, in these steel surfaces 1, the KKS is effective and corrosion protection is ensured by either immunity or passivity. At E2 of 0 V CSE, at B and C, a slightly negative value close to zero is found. This means that the passivity prevents the anodic current passage. Consequently, it can be concluded that at B and C, the pH at the steel surface 1 is sufficiently high for the formation of a protective passive film. In contrast, in the steel surface 1 A and D a significant negative voltage horn is observed, which shows anodic current passage. In this case, the conditions for passivity are not given. The KKS is therefore not effective on steel surface 1 C, since both the IR-free potential is more positive than -0.95 V CSE and also the pH is too low for the formation of a protective passive film. For B and C the protection is based on passivity and for D it is based on immunity. With steel surface 1 A, by contrast, corrosion is present.

These embodiments show how using the method locating the steel surfaces 1, the determination of the IR-free potential relative to the setpoint of -0.95 V CSE and the assessment of the corrosion state are possible.

In many cases, the voltage differences between the first reference electrode 4 and the second reference electrode 5 can be influenced by external voltage funnels or by heterogeneous moisture distribution in the ground. It is therefore important that the data can be verified by independent further measurements. This is special

4 ders essential for low voltage hoppers. From the analysis of the data in Fig. 2 it follows that in steel surfaces 1 with passivity there is no linear relationship between the different measuring points. The reason for this lies in the formation of the passive film on the steel surface. This greatly reduces the anodic current flow. If the passivity is not present, the charge passage resistance is low and the current flow is determined primarily by the propagation resistance of the steel surface 1, resulting in a linear dependence of the voltage funnels UO to U3 from the potential EO to E3. In addition to the sign and the size of U2, the passivity can also be checked by the linearity of the data. This is important because extraneous gradients can affect the voltages U0 to U3, shifting the curves in FIG. 2 up or down. The validity of the absolute values and the sign is thereby impaired.

The nonlinearity of the data in Fig. 2 in the presence of a passive film is increased when t2 is chosen as large as possible. Since redox systems such as Fe (II) / Fe (III) can be present on the steel surface 1 or the passive film must grow in thickness at the potential E2, it can also lead to a greater anodic current and thus to a more negative value of U2 in the case of passivity come, which could be interpreted as corrosion. In the presence of passivity, however, the anodic current will decrease in size, while it remains largely constant in corrosion. This effect is shown in Fig. 3 for the case of a steel surface 1 A with passivity and a steel surface 1 B with corrosion. The recording of U2 as a function of time can therefore further improve the evaluation of the present state of corrosion.

The linearity at negative potentials EO, E1 and E3 is due to the evolution of hydrogen on the steel surface

1, while the deviation from the linearity is caused by the formation of the passive film. Since the evolution of hydrogen depends on the pH of the steel surface 1, the data in Figure 2 can be used to determine the pH, ideally with a numerical simulation. In order for the determination to be as exact as possible, it may be useful to greatly increase the number of potentials and to perform a fine grading of the potentials in the area of the deviation from the linearity. In addition, it makes sense to determine other parameters such as the soil resistance, but also the laying depth of the pipeline, the exact course of the voltage gradient and the AC voltage.

The problem is that it can come along the pipeline to voltage drops due to the protective current. This effect is particularly relevant for poorly coated piping. But it is also possible that the pipe potential is influenced by direct current. 4, the potentials E0 to E3 can be measured with a voltage measuring device 13 against a reference electrode 12, which is laterally far away from the steel structure 2 with the electrolyte at one or more of the nearest measuring contacts 1 1 3 is in contact and preferably on remote soil, are measured. If there are deviations from the nominal values, adaptations to the protective current device 7 can be made via telecontrol. If severe time variations occur, the voltage measuring device 13 can make corrections to the protective current device 7 in real time. It is taken into account that when adjusting individual potentials E0 to E4, but preferably E1, the average time over the pipeline is maintained.

Alternatively, it is also possible to greatly increase the number of potentials and to drive a cyclic voltage ramp which is e.g. may have a sine shape, a triangular shape, a sawtooth shape, or any other temporal variation. It is important that the protective current device 7 at least briefly also applies anodic currents on the line. In this case, the potential measured with the voltmeter 13 against the reference electrode 12 must be continuously detected. Over the measuring time, it is then possible to match the voltage measured between the first reference electrode 4 and the second reference electrode 5 with the measured data measured by the voltage measuring device 13 at the measuring contact 1 1. Thus, each voltage U0 to U3 between the first reference electrode 4 and the second reference electrode 5 can be assigned a potential E0 to E3. Of course, it is also possible to transmit the values from the voltage measuring device 13 via radio in real time to the voltage measuring device 6, so that the results are immediately available.

In Fig. 5, the adjustments are shown, which can be made at a grounding systems 15 to allow rapid switching of the potentials EO to E3. In this way, no time is lost for charging and discharging a capacitor 14. For this purpose, the number of capacitors to increase and a changeover switch 16 to install, which synchronizes with the switch 8 in the device 7, the different capacitors. Ideally, the number of capacitors 14 corresponds to the number of potentials E0 to E3. In this way, the capacitors always remain charged and no time is lost for reloading processes.

Of course, the method is not limited to the example discussed. So it is of course possible to reduce the number of potentials to two or three or increase it as desired. In addition, the potentials can be applied to the steel structure 2 by a plurality of devices 7 connected to one or more electrodes 10, each of the devices 7 applying only one or more of the different potentials E0 to EX. Instead of DC voltage sources 9, it is also possible to use capacitors 14 instead, the grounding system 15 assuming the function of the electrode 10. However, it is essential that at least two different potentials EO and E1 are applied to the steel structure 2 by current flow from a current source 9 or a capacitor 14. Ideally, at least one potential EY will be a positive anodic current on the steel structure

2 applied. Likewise, it may be sufficient to perform this switching once to a single already

5

Claims (22)

to examine steel surface 1 identified by other methods with respect to the presence of a passive film. When the potential is cyclically switched, it is important that the time average is set in such a way that the negative effects of the measurement on the structure are minimized, since otherwise the significance of the measurement will be impaired with increasing measurement duration. Likewise, it is possible to temporarily interrupt the current flow of the device 7 between the individual potentials E0 to EX or after each sequence of the potentials E0 to EX. Of course, the method can also be carried out on a test plate. Instead of measuring the voltages UO to UX, the current IO to IX can be measured directly. This is proportional to the voltages UO to UX and allows identical analyzes. It is also possible, for example in the evaluation of test sheets, to measure the currents 10 to IX directly with a current measuring device or with the aid of the voltage drop via a shunt resistor. Further, the first reference electrode 4 and the second reference electrode 5 may be made of any material or of any type. In particular, the steel structure 2 can be used instead of the second reference electrode 5. In addition, the method can of course be applied to other steel surfaces 1 and in other electrolytes 3, such as reinforcing steel in concrete to determine the corrosion state. In these cases, it may be appropriate that the electrode 10 is displaced together with the first reference electrode 4. claims A method of locating a steel surface (1) in contact with an electrolyte (3) on a steel structure (2) and detecting its corrosion state by measuring the currents (IO) to (IX) with an ammeter or as voltages (U0) to (UX) between a first reference electrode (4) and a second reference electrode (5), both of which are in contact with the electrolyte (3), with a voltmeter (6), characterized in that one or more Devices (7) by current flow between the steel structure (2) and one or more electrodes (10) which are in contact with the electrolyte (3), potentials (E0) to (EX) for the durations (to) to (tx) on the steel structure (2) apply. 2. The method according to claim 1, characterized in that the steel structure (2) is enveloped. 3. Process according to claims 1 and 2, characterized in that the steel structure is cathodically protected. 4. The method according to any one of the preceding claims, characterized in that an arbitrarily large number of potentials (EO) to (EX) through the device (7) on the steel structure (2) is applied, wherein X preferably values of 1, 2 or 3 has. 5. The method according to any one of the preceding claims, characterized in that one of the potentials (EO) to (EX) has a value between -1 V CSE and -0.8 V CSE. 6. Method according to one of the preceding claims, characterized in that the difference between the most positive potential (EX) and the most negative potential (EZ) is greater than 0.1 V, but preferably between 1 V and 30 V. 7. The method according to any one of the preceding claims, characterized in that the sum of the periods (to) to (tX) is greater than 0.001 seconds, but preferably between 1 and 60 seconds. 8. The method according to any one of the preceding claims, characterized in that the time average of the potentials (EO) to (EX) negative than 0 V CSE, but preferably more negative than -0.85 V CSE and ideally comparable to the usual potential of the steel structure (2 ). 9. The method according to any one of the preceding claims, characterized in that the dependence of the voltages (UO) to (UX) of the potentials (EO) to (EX) for the assessment of the corrosion state of the steel surface (1) is used. 10. The method according to any one of the preceding claims, characterized in that the dependence of the voltages (UO) to (UX) of the potentials (EO) to (EX) for the assessment of the corrosion state of the steel surface (1) is used, wherein the linearity be interpreted as corrosion and nonlinearity as passivity. 11. Method according to one of the preceding claims, characterized in that the temporal variation of the absolute value of the voltage (UX) at a potential (EX) is used for the assessment of the passivity of the steel surface (1), wherein the measuring duration (tX) is preferably is greater than 3 seconds. 12. Method according to one of the preceding claims, characterized in that the temporal variation of the absolute value of the voltage (UX) at a potential (EX) is used for the assessment of the passivity of the steel surface (1), wherein the reduction of the voltage (UX) is interpreted as passivity over time. 13. The method according to any one of the preceding claims, characterized in that at least one of the potentials (EO) to (EX) leads to an anodic current flow to the steel structure (2). 14. Method according to one of the preceding claims, characterized in that the adjustment of the potentials (E0) to (EX) of the steel structure (2) by the device (7) on the basis of the potential values (E0) to (EX) measured by a voltage measuring device ( 13) takes place at an arbitrary measuring contact (1 1) against a reference electrode (12). 6 15. The method according to any one of the preceding claims, characterized in that the first reference electrode (4) or the first reference electrode (4) and the second reference electrode (5), which are all in contact with the electrolyte (3) along the steel structure ( 2) are moved to locate the steel surface (1) in contact with the electrolyte (3) and to detect their corrosion state. 16. The method according to any one of the preceding claims, characterized in that the electrode (10) adjacent to the first reference electrode (4) above the steel structure with the electrolyte (3) is brought into contact. 17. The method according to any one of the preceding claims, characterized in that one or more devices (7) the potentials (EO) to (EX) via a switch (8) and a number of DC voltage sources (9) and / or capacitors (14) apply the steel structure (2). 18. The method according to any one of the preceding claims, characterized in that a changeover switch (16) synchronously with the device (7) between a plurality of capacitors (14), which are connected to a grounding system (15), switches. 19. The method according to any one of the preceding claims, characterized in that the tension measuring device (6) with the device (7) is synchronized. 20. The method according to any one of the preceding claims, characterized in that the current IO to IX is measured with a current measuring device or as a voltage UO to UX via a shunt resistor. 21. The method according to any one of the preceding claims, characterized in that the steel structure (2) instead of the second reference electrode (5) for measuring the voltages (UO) to (UX) using the tension measuring device (6) is used. 22. The method according to any one of the preceding claims, characterized in that the dependence of the voltages (UO) to (UX) of the potentials (EO) to (EX) for the determination of the pH on the steel surface (1) is used. 7