RU2660539C1 - System of automatic correction of protective potentials of cathodic protection station - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to field of corrosion protection and can be used to correct the value of protective potential along the length of pipeline for its effective protection. System contains master and slave stations of cathodic protection with controllable power modules, adjustable safety value setting devices, reference electrodes, remote potential measurement points, communication lines, correction registers, comparison units, load cells of power module, normalizing amplifiers, setters of lower and upper permissible level of protective potential of cathodic protection slave stations and remote points, comparison elements of lower and upper permissible level of protective potential, setters of maximum permissible load level of controlled power module of cathodic protection slave stations, elements of logical addition, setters of potential points of protective potential measurement and potential comparison blocks of master station of cathodic protection.

EFFECT: improving efficiency of gas pipeline protection against corrosion by eliminating self-oscillations of protective potential by monitoring limit values of protective potential at slave stations and remote points of measurement of protective potentials and formation of control actions with inclusion of communication line only for a period of time of fixing output of protective potential beyond established limit values.

1 cl, 1 dwg

Description

The invention relates to the field of corrosion protection and can be used for automatic correction of the value of the protective potential along the length of the pipeline for its effective protection.

A known system of cathodic protection, which contains a transformer, a rectifier, the positive terminal of which is connected to the anode ground electrode, two silicon valves, two adjustable resistances, and the negative terminal of the rectifier is connected to the common point of the cathodes of silicon valves connected to each other, the anodes of which are connected to each of the protected structures through adjustable ballast resistances (RF Patent No. 2151218, CL G23F 13/00, 2003).

A disadvantage of the known device is the low efficiency of cathodic protection when exposed to external electric fields in the soil from various sources, contributing to the flow of currents and increased corrosion.

A device for cathodic corrosion protection is known, comprising a transformer, a rectifier, a reference electrode, an initial protective potential value adjuster, a potential correction unit (RF Patent No. 2394943, class C23F 13/02, 2010).

The disadvantage of this device is the low efficiency of protecting pipelines from corrosion due to possible deviations of the protective potential values along the length of the pipeline, leading to a violation of the corrosion protection process and the value of the protective potential going beyond acceptable limits.

A known system of automatic correction of the operation of cathodic protection stations, containing the first and second slave cathodic protection stations with controlled power modules, adjustable value adjusters of the initial protective potential of the first and second slave cathodic protection stations, comparison electrodes of the first and second slave cathodic protection stations, comparison electrodes of the first and the second remote points and potential switches connected to the inputs of the blocks for comparing the potential of remote points, and a communication line (RF Patent No. 2465570, CL G01N 17/02, 27 .10.2012).

A disadvantage of the known device is the low efficiency of cathodic protection when exposed to external unsteady electric fields due to the instability of maintaining the protective potential values along the length of the gas pipeline and at remote points and the uneven loading of cathodic protection stations when working on a single gas pipeline to compensate for the effects of external unsteady electric fields from various sources.

The closest is an adaptive automatic correction system for the operation of cathodic protection stations, containing the first and second slave cathodic protection stations with controlled power modules, adjustable adjusters for the initial protective potential of the first and second slave cathodic protection stations, comparison electrodes for the first and second slave cathodic protection stations, electrodes comparing the first and second remote points and potential adjusters are connected to the inputs of the blocks for comparing the potential of remote points, a communication line, I encroach on the cathodic protection station, including the first, second and third correcting adders, the corrector, the initial value of the protective potential of the leading cathodic protection station, the comparison unit, the power module, the load module of the power module, the reference electrode, the first, second, third and fourth normalizing potential amplifiers remote points, the fifth and sixth normalizing potential amplifiers of the slave cathodic protection stations, the seventh and eighth standardizing amplifiers of the potential of the leading cathodic protection station, the ninth and tenth load cell amplifier amplifiers of the power module of the leading cathodic protection station, eleventh and twelfth load cell amplifying amplifiers of power modules of the slave cathodic protection stations, first and second slave cathodic protection stations with controlled power modules, the first and second corrector, comparison blocks and load sensors of the controlled power are introduced modules of the first and second slave cathodic protection stations (RF Patent No. 2621882, cl. G01N 17/02, 07/07/2017).

A disadvantage of the known device is the presence of self-oscillations of the protective potential in the process of controlling a group of remote cathodic protection stations and increased costs for providing continuous communication of the leading cathodic protection station with remote slave cathodic protection stations and remote points of protective potential measurement, which reduces the efficiency of corrosion protection during operation by a single gas pipeline.

The objective of the invention is to increase the efficiency of protecting the gas pipeline from corrosion by eliminating self-oscillations of the protective potential by monitoring the lower and upper limit values of the protective potential at remote slave stations of cathodic protection and remote measuring points of protective potentials and the formation of control actions with the inclusion of a communication line only for a period of time fixing the output of the protective potential for the set limit values and the correction time of the protective potential along the length of the gas water.

This goal is achieved by the fact that in the system of automatic correction of protective potentials of cathodic protection stations, containing the first and second slave cathodic protection stations with controllable power modules, adjustable adjusters of the magnitude of the initial protective potential of the first and second slave cathodic protection stations, comparison electrodes of the first and second slave stations cathodic protection, electrodes comparing the first and second remote points, communication lines, a leading cathodic protection station, including the first, second and third correction timing adders, corrector, initial protective potential value setter, comparison unit, power module, load module of the power module of the cathodic protection master station, reference electrode, first, second, third and fourth normalizing potential amplifiers of remote points, fifth and sixth normalizing potential amplifiers of slave stations cathodic protection, the seventh and eighth standardizing amplifiers of the potential of the leading station cathodic protection, the ninth and tenth standardizing amplifiers of the load sensor of the power module of the leading station cathodic protection, eleventh and twelfth standardizing amplifiers of load sensors of power modules of slave cathodic protection stations, slave cathodic protection stations with controlled power modules contain first and second corrector, comparison blocks and load sensors of controlled power modules of the first and second slave cathodic protection stations, outputs of controlled power modules of the first and second slave stations of cathodic protection through load sensors and communication lines are connected to the inputs of the eleventh and twelfth normalizing amplifier If the load sensors of the power modules of the slave cathodic protection stations, respectively, the outputs of the comparison electrodes of the first and second slave cathodic protection stations are connected to the second inputs of the comparison blocks and through the communication line with the fifth and sixth normalizing potential amplifiers of the first and second slave cathodic protection stations, respectively, the first inputs of the blocks comparing, through adjustable adjusters, the values of the initial protective potential of the first and second slave cathodic protection stations, the first and second correctors, and the communication line connected to the outputs of the second and third correction adders, respectively, the outputs of the comparison blocks are connected to the control inputs of the controlled power modules of the first and second slave cathodic protection stations, respectively, the output of the power module of the leading cathodic protection station through a load sensor is connected to the ninth and tenth normalizing amplifiers of the load module of the power module the leading cathodic protection station, the output of the reference electrode of the leading cathodic protection station is connected to the seventh and eighth normalizing amplifiers potentials and with the second input of the comparison unit, the first input of which is connected to the output of the first correcting adder through the setpoint of the initial protective potential and the corrector, and the output is connected to the control input of the power module of the leading cathodic protection station, the outputs of the first and third normalizing potential amplifiers of remote points, fifth and sixth standardizing amplifiers of potential of slave stations of cathodic protection, eleventh and twelfth standardizing amplifiers of load sensors of power modules of slave stations cathodic protection connected to the inputs of the first correcting adder of the leading cathodic protection station, the outputs of the second normalizing potential amplifier of the remote point, the ninth normalizing amplifier of the load sensor of the power module of the leading cathodic protection and the seventh normalizing potential amplifier of the leading station of cathodic protection are connected to the inputs of the second correcting adder of the leading station cathodic protection, the outputs of the fourth normalizing amplifier of the potential of the remote point, the tenth normalizing amplification The load sensor of the power module of the leading cathodic protection station and the eighth normalizing potential amplifier of the leading cathodic protection station are connected to the inputs of the third correcting adder of the leading cathodic protection station, and the lower permissible protective value level controller is additionally introduced into the first and second slave cathodic protection stations with controlled power modules slave stations of cathodic protection, master of the upper permissible level of protective potential of slave stations of cathodic protection you, a comparator of the lowest permissible level of protective potential of the slave cathodic protection stations, a comparator of the highest permissible level of protective potential of the slave cathodic protection stations, a setter for the maximum permissible load level of the controlled power module of the slave cathodic protection stations, a comparator of the maximum permissible load level of the controlled cathodic protection station slave cathodic protection stations and a logical addition element of the first and second slave cathodic protection stations, in the first and the second remote protective potential measurement points, an additional lower potential protection level value for the protective potential measuring points, a higher potential protective level reference value for the remote protective potential measuring points, a lower acceptable level protection potential comparator of the remote protective potential measuring points, an upper comparator are introduced permissible level of protective potential value of remote measuring points of protective potentials and an element of logical addition of the first and second remote points of measurement of protective potentials, potential switches of the first and second remote points of measurement of protective potentials and blocks for comparing the potentials of the first and second remote points of measurement of protective potentials are added to the leading station of cathodic protection, and in the leading station of cathodic protection the first input of the potential comparison unit of the first remote measuring point of the protective potential is connected to the output of the potential adjuster of the first remote protective potential measuring glasses, the second input through the communication line is connected to the comparison electrode of the first remote point, and the output is connected to the inputs of the first and second normalizing potential amplifiers of the remote points, the first input of the potential comparison unit of the second remote protective potential measuring point is connected to the output of the second potential remote measuring points of the protective potential, the second input through the communication line is connected to the comparison electrode of the second remote point, and the output is connected to the inputs of the third and four In the first and second slave cathodic protection stations with controlled power modules, the output of the lower permissible level of the protective potential value is connected to the first inputs of the comparator of the lower acceptable level of the protective potential value, the second input of which is connected to the output of the comparison electrode, and the output with the input of the logical addition element of the first and second slave stations of the cathodic protection, the output of the setpoint of the upper permissible level of the protective sweat It is connected to the first inputs of the comparator of the upper permissible level of the protective potential, the second input of which is connected to the output of the comparison electrode, and the output with the input of the logical addition element of the first and second slave cathodic protection stations, the output of the master of the maximum allowable load level of the controlled power module is connected to the first inputs comparator of the maximum allowable load level of the controlled power module, and the output with the input of the logical addition element of the first and second slave stations cathode protection, the output of the logical addition element is connected to the control input of the communication line of the first and second slave stations of cathodic protection, respectively, at the first and second remote points of measurement of protective potentials, the first input of the comparator of the lowest permissible level of the value of the protective potential is connected to the output of the regulator of the lower permissible level of the value of the protective potential , the second input is connected to the output of the comparison electrode, and the output is connected to the input of the logical addition element of the first and second remote measurement points I of protective potentials, the first input of the comparator of the upper permissible level of the value of the protective potential is connected to the output of the master of the upper permissible level of the value of the protective potential, the second input is connected to the output of the comparison electrode, and the output is connected to the input of the logical addition element of the first and second remote points of measurement of protective potentials, output logical addition element is connected to the control input of the communication line of the first and second remote points of measurement of protective potentials, respectively.

The drawing shows a structural diagram of a system of automatic correction of protective potentials of cathodic protection stations.

The system of automatic correction of protective potentials of cathodic protection stations, contains the first 1 and second 2 slave cathodic protection stations with controlled power modules 3, adjustable adjusters 4 values of the initial protective potential of the first and second slave cathodic protection stations, comparison electrodes 5 of the first and second slave cathodic protection stations , comparison electrodes 6 of the first 7 and second 8 remote points, communication lines 9, leading 10 cathodic protection station, including the first 11, second 12 and third 13 correcting adders, OP 14, the initial protective potential value adjuster 15, the comparison unit 16, the power module 17, the load sensor of the power module 18 of the cathodic protection master station, the comparison electrode 19, the first 20, the second 21, the third 22 and the fourth 23 normalizing potential amplifiers of remote points, fifth 24 and sixth 25 standardizing amplifiers of potential of slave cathodic protection stations, seventh 26 and eighth 27 normalizing amplifiers of potential of leading station of cathodic protection, ninth 28 and tenth 29 normalizing amplifiers of load sensor of power module of master station protection, eleventh 30 and twelfth 31 standardizing amplifiers of load sensors of power modules of slave cathodic protection stations, slave cathodic protection stations with controlled power modules contain the first 32 and second 33 correctors, comparison units 34 and load sensors 35 controlled power 3 modules of the first and second slave cathodic protection stations, adjuster of the lower 36 permissible value of the protective potential of the slave stations cathodic protection, adjuster of the lower 36 permissible level of the protective potential of the slave cathodic protection stations, comparator of the lower 38 permissible level of protective potential of the slave cathodic protection stations, comparator of the upper 39 permissible level of protective potential of the slave cathodic protection stations, setpoint for the maximum permissible load level 40 of the controlled power module 3 slave cathodic protection stations, comparator of the maximum permissible load level 41 of the controlled power module 3 of the first and second slave cathodic protection stations, element 42 of the logical addition of the first 1 and second 2 slave cathodic protection stations, master of the lower 43 permissible level of the protective potential of the remote points of measurement of protective potentials, master of the upper 44 permissible level of the value of the protective potential of the remote points of measurement of protective potentials, comparator of the lower 45 permissible level of the value of the protective potential of the remote points of measurement of protective potentials, comparator of the upper 46 of the permissible the level of the protective potential value of the remote measuring points of protective potentials, element 47 of the logical addition of the primary 7 and 8, the second remote measurement points protective potentials, potentials of the setting elements 48 and 49 and the potential comparison blocks 50 and 51 of the first 7 and second 8 remote measurement points protective potential lead 10 the cathodic protection station.

The outputs of the controlled power modules 3 of the first 1 and second 2 slave cathodic protection stations via load sensors 35 and communication lines 9 are connected to the inputs of the eleventh 30 and twelfth 31 of the normalizing load cell amplifiers 35 power modules of 3 slave cathodic protection stations, respectively, the outputs of the comparison electrodes 5 of the first 1 and the second 2 slave cathodic protection stations are connected to the second inputs of the comparison units 34 and through the communication line 9 with the fifth 24 and sixth 25 normalizing amplifiers of the potential of the first 1 and second 2 slave cathodic stations shields, respectively, the first inputs of the comparison units 34 through adjustable adjusters 4 the values of the initial protective potential of the first 1 and second 2 slave stations of cathodic protection, the first 32 and second 33 correctors and the communication line 9 are connected to the outputs of the second 12 and third 13 correcting adders, respectively, the outputs of the blocks comparisons 34 are connected to the control inputs of the controlled power modules 3 of the first 1 and second 2 slave cathodic protection stations, respectively, the output of the power module 17 of the leading 10 cathodic protection stations through a load cell hands 18 is connected to the ninth 28 and tenth 29 normalizing load cell amplifiers 18 of the power module 17 of the leading 10 cathodic protection stations, the output of the reference electrode 19 of the leading 10 cathodic protection stations is connected to the seventh 26 and eighth 27 normalizing potential amplifiers and to the second input of the comparison unit 16, the first input of which through the set value of the initial protective potential 15 and the corrector 14 is connected to the output of the first 11 correcting adder, and the output to the control input of the power module 17 of the leading 10 cathodic protection station, output The first 20 and third 22 normalizing potential amplifiers of remote points, the fifth 24 and sixth 25 standard amplifying potentials of slave cathodic protection stations, the eleventh 30 and twelfth 32 normalizing amplifiers of load sensors 35 power modules of 3 slave cathodic protection stations are connected to the inputs of the first 11 correcting adder leading 10 stations of cathodic protection, outputs of the second 21 normalizing amplifier of the potential of the remote point, the ninth 28 normalizing amplifier of the load sensor 18 of the power module 17 of the leading 10 station the cathodic protection and the seventh 26 normalizing potential amplifier of the leading 10 cathodic protection stations are connected to the inputs of the second 12 correcting adder of the leading 10 cathodic protection stations, the outputs of the fourth 23 normalizing amplifier of the remote point potential, the tenth 29 normalizing amplifier of the load sensor 18 of the power module 17 of the leading 10 cathodic protection station and the eighth 27 normalizing potential amplifier of the leading 10 cathodic protection stations are connected to the inputs of the third 13 correcting adder of the leading 10 cathodic protection stations, in the leading 10 cathodic protection station, the first input of the potential comparison unit 50 of the first 7 remote point of measuring the protective potential is connected to the output of the potential setter 48 of the first remote point of measuring the protective potential, the second input through the communication line 9 is connected to the comparison electrode 6 of the first remote point, and the output is connected with the inputs of the first 20 and second normalizing amplifiers of the potential of the remote points, the first input of the potential comparison unit 51 of the second 8 of the remote measuring point of the protective potential is connected to the output potential sensor 49 of the second remote measuring point of the protective potential, the second input through the communication line 9 is connected to the reference electrode 6 of the second remote point, and the output is connected to the inputs of the third 22 and fourth 23 normalizing potential amplifiers of the remote points, in the first 1 and second 2 slave stations of the cathode protection with controlled power modules 3, the output of the master 36 lower permissible value of the protective potential is connected to the first inputs of the comparator of the lower 38 permissible level of the protective potential, the second input for which it is connected to the output of the comparison electrode 5, and the output to the input of the logical addition element 42 of the first 1 and second 2 slave cathodic protection stations, the output of the master 37 of the permissible level of the value of the protective potential is connected to the first inputs of the comparator of the upper 39 of the permissible level of the protective potential, the second the input of which is connected to the output of the comparison electrode 5, and the output to the input of the logical addition element 42 of the first 1 and second 2 slave cathodic protection stations, the output of the setpoint generator of the maximum allowable load hands 40 of the controlled power module 3 is connected to the first inputs of the comparator of the maximum allowable load level 41 of the controlled power module 3, and the output with the input of the logical addition element 42 of the first 1 and second 2 slave cathodic protection stations, the output of the logical addition element 42 is connected to the control input of the communication line 9 of the first 1 and second 2 slave stations of cathodic protection, respectively, at the first 7 and second 8 remote points of measurement of protective potentials, the first input of the comparator of the lower 45 of the permissible level of the value of protective of the potential is connected to the output of the setter of the lower 43 permissible level of the value of the protective potential, the second input is connected to the output of the comparison electrode 6, and the output is connected to the input of the logical addition element 47 of the first 7 and second 8 remote points of measurement of protective potentials, the first input of the comparator of the upper 46 of the permissible level of magnitude the protective potential is connected to the output of the master 44 of the permissible level of the value of the protective potential, the second input is connected to the output of the reference electrode 6, and the output is connected to the input of the element 47 of logical addition of the first 7 and second 8 remote points of measurement of protective potentials, the output of element 47 of logical addition is connected to the control input of the communication line 9 of the first 7 and second 8 remote points of measurement of protective potentials, respectively.

The system of automatic correction of protective potentials of cathodic protection stations operates as follows.

Leading 10, first 1 and second 2 slave cathodic protection stations form a protective potential along the length of the protected gas pipeline.

The values of the protective potential are initially set by the master of the magnitude of the initial protective potential 15 by the leading cathodic protection station and by the adjustable adjusters 4 by the magnitude of the initial protective potential of the first 1 and second 2 slave stations of the cathodic protection. These values are compared on the comparison unit 16 of the leading 10 stations and the comparison blocks 34 of the first 1 and second 2 slave cathodic protection stations with the values from the comparison electrodes 19 of the leading 10 and comparison electrodes 6 and the first 1 and second 2 slave cathodic protection stations, respectively.

The signals from the outputs of the comparison blocks are fed to the corresponding power blocks, which maintains the set value of the protective potential on the gas pipeline in the absence of external unsteady electric fields from various sources.

At the same time, the value of the protective potential at the first 1 and second 2 slave cathodic protection stations is within the allowable limits established by the adjusters of the lower 36 and upper 37 permissible levels of protective potential of the first 1 and second 2 slave cathodic protection stations. The value of the protective potential at the first 7 and second 8 remote points is also within the allowable limits established by the adjusters of the lower 43 and upper 44 permissible levels of protective potential value of the first 7 and second 8 remote points of measurement of protective potentials. In this case, the communication lines 9 are disconnected, the slave cathodic protection stations operate autonomously and stably maintain the value of the protective potential within acceptable limits. Self-oscillations of the value of the protective potential and communication costs are absent.

When external unsteady electric fields are manifested from various sources in the area of the gas pipeline, the values of protective potentials along its length deviate from the specified values.

When the value of the protective potential of the first 7 remote points decreases below the value set by the master of the lower 43 permissible level of the value of the protective potential, the comparator of the lower 45 of the permissible level of the value of the protective potential is activated, and the signal from its output through the logical addition element 47 is fed to the control input of the communication line 9. The communication line 9 is turned on and connects the first 7 remote point with the second input of the potential comparison unit 50 of the master station 10, where it is compared with a predetermined value determined by potential sensor 48. As a result, a mismatch signal is generated at the output of the potential comparison unit 50 of the first 7 remote measuring point of the protective potentials, which, through the second 21 normalizing amplifiers, through the second 12 correcting adders, the communication line 9 and the first 32 corrector, corrects the value of the adjusted setpoint 4 of the initial protective value potential. On the comparison unit 34, a signal is generated which, through the controlled power 3 module of the first 1 slave station, corrects the value of the protective potential. Also, the signal from the output of the potential comparison unit 50 of the first 7 remote point of measurement of protective potentials is supplied through the first 20 normalizing amplifier, the first 11 correction adder and corrector 14 to the initial value of the protective potential 15 of the master station 10. As a result, a signal is generated on the comparison unit 16, which by means of a controlled power 17 module of the leading 10 station adjusts the value of the protective potential.

As a result, when the value of the protective potential at the first 7 remote points is lower than the permissible value, its correction is carried out by the first 1 remote and leading 10 cathodic protection stations.

When the protective potential of the first 7 remote points increases under the action of disturbances above the value set by the master of the upper 44 of the permissible level of the value of the protective potential, the comparator of the upper 46 of the permissible level of the value of the protective potential is triggered, and the signal from its output through the logical addition element 47 is fed to the control input of the communication line 9. The communication line 9 is turned on and connects the first 7 remote point with the second input of the potential comparison unit 50 of the master station 10, where it is compared with a given value determined by the potential setter 48. As a result, a mismatch signal is generated at the output of the potential comparison unit 50 of the first 7 remote measuring point of the protective potentials, which, through the second 21 normalizing amplifiers, through the second 12 correcting adder, the communication line 9 and the first 32 corrector corrects the value of the correctable setpoint 4 values initial protective potential. On the comparison unit 34, a signal is generated which, through the controlled power 3 module of the first 1 slave station, corrects the value of the protective potential. Also, the signal from the output of the potential comparison unit 50 of the first 7 remote point of measurement of protective potentials is supplied through the first 20 normalizing amplifier, the first 11 correcting adder and corrector 14 to the initial value of the protective potential 15 of the master station 10. A signal is generated on the comparison unit 16, which is controlled by power 17 of the module of the leading 10 station adjusts the value of the protective potential.

As a result, when the protective potential at the first 7 remote points is increased above the permissible value, its correction is carried out by the first 1 remote and leading 10 cathodic protection stations.

Similarly, when the protective potential of the second 8 remote points decreases or increases beyond the limits set by the adjusters of the lower 43 and upper 44 permissible levels of the protective potential, the comparator of the lower 45 and upper 46 permissible levels of the protective potential is triggered, and the signal through the logical addition element 47 is fed to control input of the communication line 9. The communication line 9 is turned on and connects the second 8 remote point with the second input of the potential comparison unit 51 of the master station 10, where it is compared with the rear the value determined by the setpoint switch 49 of the second 8 remote point of measurement of protective potentials. As a result, a mismatch signal is generated at the output of the potential comparison unit 51 of the second 8 remote measuring point of the protective potentials, which, through the fourth 23 normalizing amplifier through the third 13 correcting adder, the communication line 9 and the second 33 corrector, corrects the value of the adjusted setter 4 of the initial protective potential value. On the comparison unit 34, a signal is generated which, through the controlled power 3 module of the second 2 slave station, corrects the value of the protective potential. Also, the signal from the output of the potential comparison unit 51 of the second 8 remote measuring point of protective potentials is supplied through the third 22 normalizing amplifier, the first 11 correcting adder and corrector 14 to the initial value of the protective potential 15 of the master station 10. As a result, a signal is generated on the comparison unit 16, which, through a controlled power 17 module of the leading 10 station, adjusts the value of the protective potential.

As a result, when reducing or increasing the value of the protective potential at the second 8 remote point beyond the established limits, its correction is carried out by the second 2 remote and leading 10 cathodic protection stations.

When the protective potential decreases or increases at the first 1 or second 2 slave cathodic protection stations and its value goes beyond the permissible protective potential level set by the lower 36 or upper 37, the comparator of the lower 38 or upper 39 permissible protective potential value of the cathodic slave stations is triggered protection and the signal through the logical addition element 42 is fed to the control input of the communication line 9. The communication line 9 is turned on and connects the comparison electrodes 5 of the first 1 or second 2 leads Mykh cathodic protection stations 24 through the fifth or sixth normalizing amplifier 25 capacity slave stations cathodic protection to a first adder 11 correction.

As a result, at the output of the first 11 correcting adder, the signal magnitude changes, and the corrector 14 corrects the task value of the setpoint of the value of the initial protective potential 15, which is compared on the comparison unit 16 with the current value of the protective potential from the comparison electrode 19. An error signal is generated at the output of the comparison unit 16 , controlling the power module 17 of the leading 10 cathodic protection stations, thereby compensating for the arising disturbances of the protective potential.

When changing the protective potential of the leading 10 cathodic protection stations, the signal from the reference electrode 19 through the seventh 26 normalizing potential amplifier is fed to the second 12 correcting adder, from the output of which through the communication line 9, the first 32 corrector, the adjustable adjuster 4 values of the initial protective potential of the first 1 slave cathodic protection station, the comparison unit 34 is supplied to a controlled power module 3 of the first 1 slave cathodic protection station. As a result, the operation of the first 1 slave cathodic protection station is adjusted to maintain the protective potential within specified limits.

Similarly, for the second 2 slave cathodic protection station, the signal from the reference electrode 19 through the eighth 27 normalizing potential amplifier is supplied to the third 13 correcting adder, from the output of which through the communication line 9, the second 33 corrector, the adjustable setpoint 4 of the value of the initial protective potential of the second 2 slave cathodic station protection, the comparison unit 34 is fed to a controlled power module 3 of the second 2 slave station cathodic protection. As a result, the operation of the second 2 slave cathodic protection station is adjusted to maintain the protective potential within specified limits.

To organize uniform loading of cathodic protection stations operating on a single extended gas pipeline, and to compensate for possible overloads, each station has load sensors for power modules.

When the power module 3 of the first 1 slave cathodic protection station is overloaded, the signal from the load sensor 35 is fed to the second input of the comparator of the maximum allowable load level 41 of the controlled power module 3. The signal from the master of the maximum allowable load level of 40 is controlled to the first input of the comparator of the maximum allowable load level 41 power module 3 and when exceeding the maximum allowable load level on the comparator 41, a signal is generated, which through and element 42 of the logical addition of the first 1 slave with Antium cathodic protection includes a communication link 9, connecting the output of the load sensor 35 of the first slave stations 1 cathodic protection through eleventh normalizing amplifier 30 to a first adder 11 correction.

When overloading the power module 3 of the second 2 slave cathodic protection station, the signal from the load sensor 35 is similarly fed to the second input of the comparator of the maximum permissible load level 41, the first input of which is supplied with a signal from the master of the maximum permissible load level 40 of the controlled power module 3. If the maximum permissible the load level on the comparator 41, a signal is generated, which through and element 42 of the logical addition of the second 2 slave stations of the cathodic protection includes a communication line 9, connecting the output of the sensor Single load 35 second slave stations 2 of cathodic protection through twelfth normalizing amplifier 31 to a first adder 11 correction.

As a result, at the output of the first 11 correcting adder, a signal will be corrected, which through the corrector 14, the initial value of the protective potential 15 and the comparison unit 16 will lead to a change in the operating mode of the power module 17 of the 10 leading cathodic protection station. In this case, part of the load of the first 1 or second 2 slave cathodic protection stations is redistributed to the leading 10 cathodic protection station. When the load is reduced at the first 1 and second 2 slave cathodic protection stations, a similar redistribution to the leading 10 cathodic protection station occurs.

The magnitude of the load of the power module 17 of the leading 10 cathodic protection stations through the ninth 28 and tenth 29 normalizing amplifiers is transmitted from the load sensor 18 of the power module of the leading 10 cathodic protection stations to the second 12 and third 13 correcting adders, respectively, and then through the first 32 and second 33 correctors to adjustable adjusters 4, comparison units 34 and controlled power modules 3.

As a result, the load balancing of the power modules of the leading and slave cathodic protection stations operating on a single extended gas pipeline takes place. The contribution of the leading and slave cathodic protection stations to the process of regulating the protective potentials along the length of the gas pipeline and the load of the power modules is determined by the setting of normalizing amplifiers of the system of automatic correction of the protective potentials of the cathodic protection stations.

Thus, the system of automatic correction of the protective potentials of cathodic protection stations provides an increase in the efficiency of protecting the gas pipeline from corrosion by eliminating self-oscillations of the protective potential by monitoring the lower and upper limit values of the protective potential at remote slave cathodic protection stations and at remote points for measuring protective potentials and generating control actions with switching on communication lines only for a period of time fixing the exit of the protective potential beyond the established limit values and time of correction of protective potential along the length of the gas pipeline.

Claims (1)

A system for automatically correcting the protective potentials of cathodic protection stations, comprising a leading, first and second slave cathodic protection stations with controllable power modules, adjustable adjusters for the initial protective potential of the first and second slave cathodic protection stations, comparison electrodes for the first and second slave cathodic protection stations, comparison electrodes first and second remote points, a communication line, a cathodic protection master station, including first, second and third correcting adders, a corrector, initial protective potential value sensor, comparison unit, power module, load module of the power module of the cathodic protection master station, comparison electrode, first, second, third and fourth rated potential amplifiers of remote points, fifth and sixth rated potential amplifiers of slave cathodic protection stations, seventh and the eighth standardizing amplifiers of the potential of the leading cathodic protection station, the ninth and tenth normalizing amplifiers of the load sensor of the power module of the leading cathodic protection station, the eleventh and twelfth standardizing amplifiers of load sensors of power modules of slave cathodic protection stations, slave cathodic protection stations with controlled power modules contain first and second corrector, comparison blocks and load sensors of controlled power modules of the first and second slave cathodic protection stations, outputs of controlled power modules of the first and second slave cathodic protection stations through load sensors and communication lines are connected to the inputs of the eleventh and twelfth normalizing amplifiers of load sensors of power m the module of the slave cathodic protection stations, respectively, the outputs of the comparison electrodes of the first and second slave cathodic protection stations are connected to the second inputs of the comparison units and through a communication line with the fifth and sixth normalizing potential amplifiers of the first and second slave cathodic protection stations, respectively, the first inputs of the comparison blocks through the adjustable adjusters the values of the initial protective potential of the first and second slave cathodic protection stations, the first and second correctors and the communication line are connected to the outputs of the second and third correcting adders, respectively, the outputs of the comparison units are connected to the control inputs of the controlled power modules of the first and second slave cathodic protection stations, respectively, the output of the power module of the leading cathodic protection station via a load sensor is connected to the ninth and tenth normalizing amplifiers of the load sensor of the power module of the cathodic protection master station, the output of the reference electrode of the leading cathodic protection station is connected to the seventh and eighth normalizing potential amplifiers and to the second input the house of the comparison unit, the first input of which is connected to the output of the first correcting adder through the master value of the initial protective potential and the corrector, and the output is connected to the control input of the power module of the leading cathodic protection station, the outputs of the first and third normalizing potential amplifiers of remote points, the fifth and sixth normalizing amplifiers potential of the slave cathodic protection stations, the eleventh and twelfth rated amplifiers of load sensors of power modules of the slave cathodic protection stations are connected to by the steps of the first correcting adder of the leading cathodic protection station, the outputs of the second normalizing amplifier of the potential of the remote point, the ninth normalizing amplifier of the load sensor of the power module of the leading station of cathodic protection and the seventh normalizing amplifier of the potential of the leading station of cathodic protection are connected to the inputs of the second correcting adder of the leading station of cathodic protection, the outputs of the fourth a remote point potential regulation amplifier, tenth normalization amplifier of a load mode load sensor For the leading cathodic protection station and the eighth normalizing potential amplifier of the leading cathodic protection station are connected to the inputs of the third correcting adder of the leading cathodic protection station, characterized in that in the first and second slave cathodic protection stations with controllable power modules, a lower permissible protective potential value is added slave stations of cathodic protection, master of the upper permissible level of protective potential of slave stations of cathodic protection, compar torus of the lower permissible level of the protective potential of the slave cathodic protection stations, comparator of the upper permissible level of the protective potential of the slave cathodic protection stations, setter of the maximum allowable load level of the controlled power module of the slave cathodic protection stations, comparator of the maximum permissible load level of the controlled power module of the cathodic protection cathodic protection and an element of logical addition of the first and second slave cathodic protection stations, in the first and second remote protective potential measurement points, an additional setpoint for the lower permissible level of the protective potential value of the remote protective potential measurement points, an upper permissible protective level value for the protective potential value of the remote protective potential measurement points, a lower acceptable level comparator of the protective potential value of the remote protective potential measurement points, an upper acceptable level comparator values of protective potential of remote measuring points of protective potentials and an element of logical addition of the first and second remote points of measurement of protective potentials, potential switches of the first and second remote points of measurement of protective potentials and blocks for comparing the potentials of the first and second remote points of measurement of protective potentials are added to the leading station of cathodic protection, and the first station of the cathodic protection the input of the potential comparison unit of the first remote measuring point of the protective potential is connected to the output of the potential adjuster of the first remote measuring point of the protective potential, the second input through the communication line is connected to the comparison electrode of the first remote point, and the output is connected to the inputs of the first and second normalizing potential amplifiers of the remote points, the first input of the potential comparison unit of the second remote point of measuring the protective potential is connected to the output of the potential adjuster of the second remote point measuring the protective potential, the second input through the communication line is connected to the reference electrode of the second remote point, and the output is connected to the inputs of the third and fourth forming amplifiers of the potential of remote points in the first and second slave cathodic protection stations with controlled power modules, the output of the lower permissible level of the protective potential value is connected to the first input of the comparator of the lower acceptable level of the protective potential, the second input of which is connected to the output of the comparison electrode, and the output is with the input of the logical addition element of the first and second slave cathodic protection stations, the output of the setpoint of the upper permissible level of the value of the protective potential connected to the first input of the comparator of the upper permissible level of the protective potential, the second input of which is connected to the output of the comparison electrode, and the output to the input of the logical addition element of the first and second slave stations of cathodic protection, the output of the master of the maximum allowable load level of the controlled power module is connected to the first input comparator of the maximum allowable load level of the controlled power module, and the output with the input of the logical addition element of the first and second slave cathodic stations protection, the output of the logical addition element is connected to the control input of the communication line of the first and second slave stations of cathodic protection, respectively, at the first and second remote points of measurement of protective potentials, the first input of the comparator of the lowest permissible level of the value of the protective potential is connected to the output of the regulator of the lower permissible level of the value of the protective potential, the second input is connected to the output of the comparison electrode, and the output is connected to the input of the logical addition element of the first and second remote measurement points protective potentials, the first input of the comparator of the upper permissible level of the value of the protective potential is connected to the output of the master of the upper permissible level of the value of the protective potential, the second input is connected to the output of the comparison electrode, and the output is connected to the input of the logical addition element of the first and second remote points of measurement of protective potentials, the output of the logical addition element is connected to the control input of the communication line of the first and second remote points of measurement of protective potentials, respectively.

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