RU2582301C2 - Method to detect extended anode earthing device damage point - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: invention relates to protection of underground structures against corrosion and may be used to control operation of devices of cathode protection against corrosion. Substance: searching for the point of damage of the extended anode earthing device (EAED) by induction method is carried out in three stages using different circuits of AC sources connection to EAED and using AC with frequency below 128 Hz, excluding frequencies of 100 and 50 Hz.

EFFECT: increased accuracy of extended anode earthing device damage point, laid at distance of at least 1 m from a pipeline.

3 cl, 3 dwg, 1 tbl

Description

The invention relates to the protection of underground structures from corrosion and can be used to monitor the operation of cathodic corrosion protection devices.

The extended anode ground electrode (hereinafter PAZ) is a cable with a copper core in a conductive sheath. It is designed to protect underground structures from corrosion. In the proposed application for the grant of a patent of the Russian Federation, an anode ground electrode system for main oil pipelines and product pipelines (hereinafter referred to as MN) is considered. It is laid along the MN at a distance of 0.3 m from it. During operation, as well as during the repair of MN, there are cases of damage to the anode ground electrode. Several methods are used to search for the damage location of the cable of the anode earthing switch, see table 1.

Table 1 Comparison of cable line fault finding methods No., p.p Search methods pros Minuses Possibility of applying to search for a long A3 cliff one Acoustic Search for all types of damage. It is limited by the transition resistance of the defect of at least 40 Ohms Impossible 2 Induction High defect detection rate Confident defect determination is possible only at distances between objects more than the depth maybe 3 Potential difference measurements High defect accuracy It requires accurate placement of the electrode above the object, it does not allow to identify the defect at distances between objects less than the depth Perhaps in combination with an induction method

The analysis showed that the above methods for finding damage to extended anode grounding conductors are ineffective.

When reviewing the technical literature, technical solutions were identified that relate to determining the location of damage to extended anode grounding conductors.

The well-known "Method for determining the place of damage to the cable of a power line and communication using the marker method", including determining the distance to the place of damage of the cable line by the time of arrival of the reflected pulse from the place of damage, when exposed to the measurement object by probing pulses receive reflected pulses, subjecting them to amplification according to the law , the inverse law of the attenuation of the pulses, record the time of arrival of the pulse reflected from the place of damage or the end of the line, and determine the distance to the place of damage (s m. patent No. 2215298 dated 07/27/2003, IPC G01R 31/00).

A disadvantage of the known technical solution is the inability to search for damage on uninsulated cable lines due to the fast attenuation of the signal due to leaks in the conductive sheath of the PAZ.

The well-known “Method for determining the location of damage to cable lines”, according to which a current is passed through the cable, the magnetic field of this current is traced along the cable route using a device for measuring magnetic quantities, and the place of damage is determined by the disappearance of the magnetic field created in the damaged cable core by an electrostatic machine (see patent No. 210075 04/27/1998, IPC G01R 31/08).

A disadvantage of the known technical solution is the inability to search for damage on uninsulated cable lines due to the fast attenuation of the signal due to leaks in the conductive sheath of the PAZ.

The well-known “Method for searching cable lines and pipelines using cable detectors of the 3M Dynateb series, including the search for pipes protected from corrosion by cathode stations, use the second harmonic of an industrial frequency of 50/60 Hz (i.e. 100 Hz or 120) to search for anodes and damage to the anode bus Hz), by monitoring the signal level on the receiver’s display, when the receiver’s antenna has passed the anode bus break, the level of the received signal will weaken until it disappears (see 3M ™ Dynatel 80-6108-6216-3-С, 1998, p. 45).

A disadvantage of the known technical solution is the search for PAZ damage only at distances between the pipeline and the extended anode ground electrode more than the depth of their occurrence.

The closest technical solution for determining the location of a PAZ damage to the claimed one is the induction method based on the principle of capturing changes in the magnetic field above the PAZ, through which current is passed from the sound frequency generator (generator). In this case, an alternating magnetic field is formed around the cable, the intensity of which is proportional to the magnitude of the current in the PAZ. On the surface of the earth above the cable, using the induction frame of the receiving amplifier, a magnetic field is determined, which propagates along the path of the current through the PAZ (see G.M. . 247-266).

A disadvantage of the known technical solution is the low accuracy (± 60 m) of determining PAZ damage at distances between the pipeline and the extended anode ground electrode less than the depth of their occurrence.

The problem solved in the invention is to improve the accuracy of determining the location of the damage PAZ.

The technical result consists in increasing the accuracy of the search for places of damage to PAZ laid in close proximity to the pipeline.

The problem is solved, and the technical result is achieved by the fact that the search for the damage site of the PAZ by the induction method is carried out in three stages using various schemes for connecting AC sources to the PAZ and using alternating current with a frequency below 128 Hz, excluding the frequencies of 100 and 50 Hz.

Moreover, the method for determining the location of damage to an extended anode ground electrode system, including passing the generator current through an extended anode ground electrode system with control of its magnetic field, characterized in that the location of damage to an extended anode ground electrode system is carried out in three stages using various schemes for connecting AC sources to an extended anode ground electrode system and using alternating current with a frequency below 128 Hz, excluding frequencies of 100 and 50 Hz.

At the first stage, with a step, for example, 10 m, they measure the propagation along the extended anode earthing switch of the magnetic field of the generator connected to the extended anode earthing switch in the connecting column installed at the beginning of the tested extended anode earthing switch, and ground, while the measuring device is moved across the length of the extended anode earthing switch with determining the maximum level of the magnetic field in an extended anode earthing switch, this action is repeated for each measurement, in After measuring with the gain controller, the sensitivity of the measuring device is set to values from 70 dBl to 80 dBl, then the measuring device is moved along the line of the maximum value of the magnetic field level, the line of the extended anode ground electrode is monitored by the indicator of the measuring device and the value of the magnetic field level and the depth of the extended anode are measured earthing switch, and at the point of attenuation of the magnetic field values less than 10% of the initial value, a control sign is set.

At stage 2, measurements are taken from the end of the long extended anode ground electrode.

At the 3rd stage, on the site of the extended anode ground electrode marked with control signs, a measurement is carried out with a step of 1 m of propagation along the extended anode ground electrode of the oscillator field of the generator connected to the start and end points of the extended anode ground electrode in the connecting columns, and the magnetic field is measured in the extended anode ground electrode device, first move it across the line of the extended anode ground electrode and stop at the point of maximum magnetic field in an extended anode earthing switch, then from the control mark installed in stage 1, the measuring device is moved along the magnetic field line to the control sign installed in stage 2, the value of the magnetic field level is monitored by the indicator of the measuring device and the damage location of the extended anode ground electrode is determined by the minimum value magnetic field.

The method that implements the proposed technical solution is illustrated by the schemes shown in FIG. 1-3, where are presented:

In FIG. 1 shows a diagram of the first stage of measurement.

In FIG. 2 shows a diagram of the second stage of measurement.

In FIG. 3 shows a diagram of the third stage of measurement.

In FIG. 1-3 the following notation is applied:

1 - long anode ground electrode system (PAZ);

2 - pipeline;

3 - generator;

4 - measuring device;

5 - grounding;

6 - control mark;

7 - connecting column.

Generator 3 is designed to create a magnetic field in an extended anode ground electrode system.

The measuring device 4 is designed to measure the magnetic field around the PAZ. As the measuring device 4 can be used, for example, a current topograph.

The control sign 6 is installed in places of maximum attenuation of the magnetic field.

The search for the location of damage to an extended anode ground electrode system by induction is carried out in three stages using various schemes for connecting alternating current sources to a PAZ and using alternating current with a frequency below 128 Hz, excluding frequencies of 100 and 50 Hz.

At stage 1, with a step, for example 10 m, measure the propagation along the extended anode ground electrode 1 of the magnetic field of the generator 3 connected to the PAZ 1 in the connecting column 7 installed at the beginning of the tested PAZ 1 and ground 5 in accordance with the diagram (Fig. 1 ) The measuring device 4 is moved across the line PAZ 1 with the determination of the maximum level of the magnetic field in the PAZ 1. This action is repeated every measurement. The gain regulator sets the sensitivity of the measuring device 4 to values from 70 dBl to 80 dBl (these values are obtained experimentally and provide the best selectivity of the measuring device with minimal measurement errors). Moving the measuring device 4 along the line of the maximum value of the magnetic field level, at each measurement step, the passage line of the PAZ 1, the value of the level of the magnetic field and the depth of the PAZ 1 are controlled by the indicator of the measuring device. At the point of attenuation of the values of the magnetic field less than 10% of the initial value, the control sign 6.

In stage 2, with the step specified in stage 1, the propagation along the extended anode ground electrode 1 of the magnetic field 3 of the generator 3 connected to the PAZ 1 in the connecting column 7 installed at the end of the extended extended anode ground electrode 1 and ground 5 in accordance with the scheme ( Fig. 2). The measuring device 4 is moved across the line PAZ 1 with the determination of the maximum level of the magnetic field in the PAZ 1. This action is repeated on each measurement. The gain regulator sets the sensitivity of the measuring device 4 to values from 70 dbl to 80 dbl. Moving the measuring device 4 along the line of the maximum value of the magnetic field level at each measurement step, the passage line of the PAZ 1, the value of the level of the magnetic field and the depth of the PAZ 1 are monitored by the indicator of the measuring device. At the point of attenuation of the values of the magnetic field less than 10% of the initial value, the control sign 6.

At the 3rd stage, in the area of the extended anode ground electrode 1 marked with control signs 6, the propagation along the extended anode ground electrode 1 of the magnetic field 3 of the generator 3 connected to the start and end points of the PAZ 1 in the connecting columns 7 is measured with a step of 1 m in accordance with the scheme ( Fig. 3). Measure the magnetic field in the PAZ 1 with a measuring device 4, first move it across the line of the PAZ 1 and stop at the point of the maximum level of the magnetic field in the PAZ 1. Then from the control sign installed in step 1, move the measuring device 4 along the line of the magnetic field to the control sign installed in stage 2. The indicator of the measuring device controls the value of the magnetic field level. The point with the minimum value of the magnetic field in PAZ 1 is the place of damage to the extended anode ground electrode 1.

As a result of the implementation of the proposed technical solution, the accuracy of determining the location of damage is ensured.

Claims (3)

1. A method for determining the location of damage to an extended anode earthing switch, including passing a generator current through an extended anode earthing switch with control of its magnetic field, characterized in that the damage location of an extended anode earthing switch is carried out in three stages using alternating current with a frequency below 128 Hz, excluding frequencies 100 and 50 Hz, while
- at the first stage, along the extended anode ground electrode system, with a certain step, a measurement is made of the magnetic field propagation of the generator connected to the extended anode ground electrode system in the connecting column installed at the beginning of the extended extended anode ground electrode system, and ground, while the measuring device is moved across the extended anode ground electrode line with the definition the maximum level of the magnetic field in the extended anode earthing switch, this action is repeated for each measurement, at the beginning After measuring with the gain controller, the sensitivity of the measuring device is set to values from 70 dBl to 80 dBl, then the measuring device is moved along the line of the maximum value of the magnetic field level, the line of the extended anode ground electrode is monitored by the indicator of the measuring device and the value of the magnetic field level and the depth of the extended anode are measured the ground electrode, and at the point of attenuation of the magnetic field values less than 10% of the initial value, a control sign is set;
- at the second stage, along the extended anode ground electrode with a certain step specified at the first stage, the propagation of the magnetic field of the generator connected to the extended anode ground electrode in the connecting column installed at the end of the extended extended anode ground electrode is measured, and grounding, measurements are taken from the end of the extended extended anode earthing switch similarly to the measurements performed in the first stage;
- at the third stage, in the area of the extended anode ground electrode marked with control signs, a measuring device is used to measure the propagation along the extended anode ground electrode of the generator’s magnetic field connected to the start and end points of the extended anode ground electrode in the connecting columns , while first moving the measuring device across the line of the extended anode ground electrode and stop at the point of maximum level magnetically about the field of the extended anode ground electrode, then from the control mark installed in the first stage, move the measuring device along the magnetic field line to the control sign installed in the second stage, use the indicator of the measuring device to control the level of the magnetic field and determine the location of damage to the extended anode ground electrode value of the magnetic field. 2. The method according to p. 1, characterized in that at the first stage the measurement of the propagation of the magnetic field of the generator along the extended anode ground electrode is performed in increments of 10 m 3. The method according to p. 1, characterized in that in the third stage, the measurement of the propagation of the magnetic field of the generator in the area along the extended anode ground electrode marked with control signs, is performed with a step of 1 m

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