RU2764043C1 - Smart device of cathode protection with control of the corrosion process of a group of underground metal structures - Google Patents

Abstract

FIELD: corrosion protection.

SUBSTANCE: invention relates to the field of corrosion protection and can be used to protect gas pipelines, oil pipelines and other underground metal structures when they run in the area of ​​movement of rail electric transport. The device contains a transformer, a rectifier, a filter, anode earthing switches of the main and additional metal structures, power switches, valves, filters, integrators, modulators, sensors and generators of protective potential, comparison units, correctors, scaling amplifiers, sensors of entry and exit of the protection zone by electric transport, blocks radio broadcasts, triggers, adder, memory blocks, correction registers, corrosion control elements, totalizers for calculating the action of corrosion, integral corrosion correctors for the potential of the main and additional protected structures.

EFFECT: increasing the efficiency of cathodic corrosion protection by monitoring the amount of corrosion in real time and correcting the values ​​of protective currents in the protected area of ​​underground metal structures from the amount of real corrosion and the nature of the movement of electric rail vehicles in the area of ​​their running.

1 cl, 1 dwg

Description

The invention relates to corrosion protection of a group of underground metal structures and can be used to protect gas pipelines, oil pipelines and other underground metal structures.

An adaptive device for cathodic corrosion protection of a group of underground metal structures is known, consisting of a main and additional metal structures and containing a transformer, a rectifier, the positive terminal of which is connected to the anode ground electrode through a rectified voltage filter, series-connected power switches, valves and filters of the main and N additional protected structures, amplifiers, integrators, pulse-width modulators and control units for power switches of the main and N additional protected structures, a potential difference sensor of the main and N additional protected structures, a sensor for the magnitude of the protective potential of the main protected structure, a potential adjuster for the main protected structure, a block for comparing the main protected structures (Pat. RU No. 2440442, C23F 13/02, 2012).

The disadvantage of the known analogue is the low efficiency of cathodic corrosion protection of a group of underground metal structures when they lie in the zone of movement of rail electric vehicles.

An adaptive device for cathodic corrosion protection of a group of underground metal structures is known, containing a transformer, a rectifier, connections through a rectified voltage filter with anode ground electrodes of the main and N additional metal structures, series-connected power switches, valves and filters of the main and N additional protected structures, amplifiers, integrators , pulse-width modulators and power switch control units of the main and N additional protected structures, potential difference sensors of the main and N additional protected structures, sensors of the protective potential of the main and N additional protected structures, potential generator of the main protected structure, blocks for comparing the main and N additional protected structures, correctors of the main and N additional protected structures, scaling amplifiers of the main and N additional protected structures (Pat. RU No. 2491373, C23F 13/02, 2 013).

A disadvantage of the known device is the low efficiency of cathodic corrosion protection of a group of underground metal structures in the absence of real-time control of the magnitude of corrosion and correction of the values of protective currents in the protected zone of underground metal structures.

The closest to the invention is an intelligent device for cathodic corrosion protection of a group of underground metal structures, containing a transformer, a rectifier connected through a rectified voltage filter to the anode ground electrodes of the main and N additional metal structures, series-connected power switches, valves and filters of the main and N additional protected structures , amplifiers, integrators, pulse-width modulators and power switch control units of the main and N additional protected structures, potential difference sensors of the main and N additional protected structures, sensors of the protective potential of the main and N additional protected structures, potential generator of the main protected structure, comparison units of the main and N additional protected structures, correctors of the generators of the main and N additional protected structures, scaling amplifiers of the main and N additional protected structures zhenii, the potential generator of the main protected structure is connected to the first inputs of the correctors of the generators of the main and N additional protected structures, the sensors of the potential difference of the main and N additional protected structures through the corresponding scaling amplifiers are connected to the second inputs of the correctors of the generators of the main and N additional protected structures, respectively, the first inputs of the blocks comparing the main and N additional protected structures are connected to the outputs of the correctors of the main and N additional protected structures, the outputs with the amplifiers of the main and N additional protected structures, the first and second entry sensors and the first and second sensors for leaving the protection zone of the main and N additional protected structures by electric transport, the first and second radio transmission units, the radio reception unit, the first and second triggers, the first and second setters for the correction of the protective potential, the first and second correction keys, the adder setter a, the first and second keys of the main and N additional protected structures, the first and second blocks of memory for the values of the protective potentials of the main and N additional protected structures, the first and second corrective registers for the passage of electric transport in the area of the main and N additional protected structures, the first and second corrective amplifiers of the main and N additional protected structures, adders for correction of the main and N additional protected structures, potential correctors of the main and N additional protected structures, the first and second radio transmission units are connected to the radio reception unit via a radio channel, the first sensor for entering the electric transport into the zone of protected structures through the first radio transmission unit and the unit radio reception via the radio channel is connected to the input of the installation in unit "1" of the first trigger, the second sensor of the entry of electric transport into the zone of protected structures through the second radio transmission unit and the radio reception unit via the radio channel is connected to the input of the installation and to unit "1" of the second trigger, the output of the first trigger is connected to the control inputs of the first keys of the main and N additional protected structures, the first corrective registers of the main and N additional protected structures and the first correction key, the output of the second trigger is connected to the control inputs of the second keys of the main and N additional protected structures, the second corrective registers of the main and N additional protected structures and the second correction key, the outputs of the first and second setters for correcting the protective potential through the first and second correction keys and the adder of the setter are connected to the correcting input of the potential setter of the main protected structure, sensors for the magnitude of the protective potential the main and N additional protected structures are connected to the information inputs of the first and second keys of the main and N additional protected structures, the outputs of the first keys through the first memory blocks of the values of the protective potentials of the main and N additional protected structures, the first corrective registers for the passage of electric transport in the zone of the main and N additional protected structures and the first corrective amplifiers are connected to the first inputs of the correction adders of the main and N additional protected structures, the outputs of the second keys through the second memory blocks of the values of the protective potentials of the main and N additional protected structures, the second corrective registers for the passage of electric transport in the zone of the main and N additional protected structures and the second corrective amplifiers are connected to the second inputs of the correction adders of the main and N additional protected structures, the outputs of the correction adders are connected to the second inputs of the potential correctors of the main and N additional protected structures, the outputs of the correctors potentials are connected to the second inputs of the comparison blocks of the main and N additional protected structures (US Pat. RU No. 2741398, C23F 13/02, 2021).

The disadvantage of the known prototype is the low efficiency of cathodic protection against corrosion of a group of underground metal structures without taking into account the control of the amount of corrosion in real time and the correction of the values of protective currents in the protected zone of underground metal structures from the amount of real corrosion and the nature of the movement of rail electric transport in the zone of their passage.

The objective of the invention is to increase the efficiency of cathodic corrosion protection of a group of underground metal structures by monitoring the magnitude of corrosion in real time and correcting the values of protective currents in the protected zone of underground metal structures from the magnitude of real corrosion and the nature of the movement of rail electric transport in the area of their occurrence.

The task is achieved by the fact that in an intelligent cathodic protection device with corrosion process control of a group of underground metal structures, containing a transformer, a rectifier connected through a rectified voltage filter to the anode ground electrodes of the main and N additional metal structures, series-connected power switches, valves and filters of the main and N additional protected structures, amplifiers, integrators, pulse-width modulators and control units for power switches of the main and N additional protected structures, potential difference sensors of the main and N additional protected structures, sensors of the protective potential of the main and N additional protected structures, potential generator of the main protected structures, comparison units of the main and N additional protected structures, correctors of the masters of the main and N additional protected structures, scaling amplifiers of the main and N additional of the main protected structures, the potential generator of the main protected structure is connected to the first inputs of the correctors of the generators of the main and N additional protected structures, the sensors of the potential difference of the main and N additional protected structures through the corresponding scaling amplifiers are connected to the second inputs of the correctors of the generators of the main and N additional protected structures, respectively, the first the inputs of the comparison blocks of the main and N additional protected structures are connected to the outputs of the correctors of the main and N additional protected structures, the outputs with the amplifiers of the main and N additional protected structures, the first and second entry sensors and the first and second sensors for leaving the protection zone of the main and N additional protected structures electric transport, the first and second radio transmission units, the radio reception unit, the first and second triggers, the first and second protective potential correction setters, the first and second correction keys ii, master adder, the first and second keys of the main and N additional protected structures, the first and second memory blocks of the values of the protective potentials of the main and N additional protected structures, the first and second corrective registers for the passage of electric transport in the area of the main and N additional protected structures, the first and second corrective amplifiers of the main and N additional protected structures, correction adders of the main and N additional protected structures, potential correctors of the main and N additional protected structures, the first and second radio transmission units are connected to the radio reception unit via a radio channel, the first sensor for entering the zone of protected structures by electric transport through the first unit radio transmission and radio reception unit via the radio channel is connected to the input of the installation in unit "1" of the first trigger, the second sensor of the entry of electric transport into the zone of protected structures through the second radio transmission unit and the radio reception unit via the radio channel not with the input of setting to unity "1" of the second trigger, the output of the first trigger is connected to the control inputs of the first keys of the main and N additional protected structures, the first corrective registers of the main and N additional protected structures and the first correction key, the output of the second trigger is connected to the control inputs of the second keys of the main and N additional protected structures, the second corrective registers of the main and N additional protected structures and the second correction key, the outputs of the first and second setters for correcting the protective potential through the first and second correction keys and the adder of the setter are connected to the correcting input of the potential setter of the main protected structure, sensors the values of the protective potential of the main and N additional protected structures are connected to the information inputs of the first and second keys of the main and N additional protected structures, the outputs of the first keys through the first memory blocks of the protective sweat values of the main and N additional protected structures, the first corrective registers for the passage of electric transport in the zone of the main and N additional protected structures and the first corrective amplifiers are connected to the first inputs of the correction adders of the main and N additional protected structures, the outputs of the second keys through the second memory blocks of the values of the protective potentials of the main and N additional protected structures, the second corrective registers for the passage of electric transport in the zone of the main and N additional protected structures and the second corrective amplifiers are connected to the second inputs of the correction adders of the main and N additional protected structures, the outputs of the correction adders are connected to the second inputs of the potential correctors of the main and N additional protected structures , the outputs of the potential correctors are connected to the second inputs of the comparison blocks of the main and N additional protected structures, the first elements of the con control of the corrosion action of the main and N additional protected structures, made of the same material as the protected pipeline, and having the smallest cross section, the second elements of the control of the corrosion action of the main and N additional protected structures, made of the same material as the protected pipeline, and having an average section, the third elements for monitoring the corrosion effect of the main and N additional protected structures, made of the same material as the protected pipeline, and having the largest cross section, the first correctors for the corrosion action of the main and N additional protected structures, generating an output signal in case of corrosion destruction of the first control element corrosion effect having the smallest cross section, the second corro Corrosion test of the main and N additional protected structures, generating an output signal in the event of corrosion failure of the third corrosion control element having the largest cross section, adders for calculating the corrosion action of the main and N additional protected structures, integral correctors of the corrosion action by the potential of the main and N additional protected structures, the first and the second timers for controlling the entry of electric transport into the zone of protected structures, the first and second "OR" elements, and the first elements for controlling the effect of corrosion of the main and N additional protected structures through the first correctors for the effect of corrosion of the main and N additional protected structures, generating signals at the output during corrosion destruction the first corrosion action control elements having the smallest cross section are connected to the first inputs of the adders for calculating the corrosion action of the main and N additional protected structures, the second action control elements to corrosion of the main and N additional protected structures through the second correctors of the corrosion action of the main and N additional protected structures, generating signals at the output during corrosion damage of the second corrosion control elements having an average cross section, are connected to the second inputs of the adders for calculating the corrosion action of the main and N additional protected structures , the third corrosion control elements of the main and N additional protected structures through the third corrosion action correctors of the main and N additional protected structures, which generate output signals in case of corrosion damage of the third corrosion control elements having the largest cross section, are connected to the third inputs of the adders for calculating the corrosion action of the main and N additional protected structures, the common outputs of the third elements for monitoring the corrosion action of the main and N additional protected structures are connected to the common inputs of the adders for calculating the action corrosion effects of the main and N additional protected structures, the outputs of the adders for calculating the corrosion effect of the main and N additional protected structures are connected to the second inputs of the integral correctors of the corrosion action by the potential of the main and N additional protected structures, the sensors of the protective potential of the main and N additional protected structures are connected to the first the inputs of the integral correctors of the corrosion action according to the potential of the main and N additional protected structures, the outputs of which are connected to the first inputs of the potential correctors of the main and N additional protected structures, the first sensor for entering the zone of the protected structures by the first radio transmission unit and the radio reception unit via the radio channel is connected to the launch input the first timer to control the entry of electric transport into the zone of protected structures, the second sensor for the entry of electric transport into the zone of protected structures through the second radio transmission unit and the radio reception via a radio channel is connected to the start input of the second timer for controlling the entry of electric transport into the zone of protected structures, the output of the first timer for controlling the entry of electric transport into the zone of protected structures through the first element "OR" is connected to the reset input to "0" of the first trigger, the output of the second timer for controlling the entry of electric transport to the zone of protected structures through the second element "OR" is connected to the reset input to "0" of the second trigger, the first sensor for leaving the zone of protected structures by electric transport through the first radio transmission unit and the radio reception unit via the radio channel, the second element "OR" is connected to the reset input to "0" » of the second trigger, the second sensor for leaving the zone of protected structures by electric transport through the second radio transmission unit and the radio reception unit via the radio channel, the first "OR" element is connected to the reset input to "0" of the first trigger.

The figure shows a diagram of an intelligent cathodic protection device with control over the corrosion process of a group of underground metal structures.

The device contains a transformer 1, a rectifier 2, connections through a filter 3 of the rectified voltage with anode ground electrodes 4 of the main and N additional metal structures, power switches 5 connected in series, valves 6 and filters 7 of the main and N additional protected structures, amplifiers 8, integrators 9, width - pulse modulators 10 and control units 11 with power switches of the main and N additional protected structures, potential difference sensors 12 of the main and N additional protected structures, sensors of the protective potential 13 of the main and N additional protected structures, potential generator 14 of the main protected structure, comparison units 15 main and N additional protected structures, correctors of the generators 16 of the main and N additional protected structures, scaling amplifiers 17 of the main and N additional protected structures, the potential generator 14 of the main protected structure is connected to the first inputs correctors of the setters 16 of the main and N additional protected structures, the potential difference sensors 12 of the main and N additional protected structures through the corresponding scaling amplifiers 17 are connected to the second inputs of the correctors of the setters 16 of the main and N additional protected structures, respectively, the first inputs of the comparison units 15 of the main and N additional protected structures structures are connected to the outputs of the correctors of the generators 16 of the main and N additional protected structures, the outputs of the comparison block of the main and N blocks of comparison of additional protected structures are connected to the amplifiers of the main and N additional protected structures, the first 18 and second 19 entry sensors and the first 20 and second 21 exit sensors protection zones of the main and N additional protected structures by electric transport, the first 22 and 23 second radio transmission units, the radio reception unit 24, the first 25 and 26 second triggers, the first 27 and 28 second 28 protective sweat correction adjusters entsial, the first 29 and second 30 correction keys, the adder 31 of the master, the first 32 and second 33 keys of the main and N additional protected structures, the first 34 and second 35 memory blocks of the values of the protective potentials of the main and N additional protected structures, the first 36 and second 37 corrective electric transport passage registers in the zone of the main and N additional protected structures, the first 38 and the second 39 corrective amplifiers of the main and N additional protected structures, correction adders 40 of the main and N additional protected structures, potential correctors 41 of the main and N additional protected structures, the first elements of control of the action corrosion 42 of the main and N additional protected structures, made of the same material as the protected pipeline, and having the smallest cross section, the second corrosion control elements 43 of the main and N additional protected structures, made of the same material as the protected pipeline water, and having an average cross section, the third elements of corrosion control 44 of the main and N additional protected structures, made of the same material as the protected pipeline, and having the largest cross section, the first correctors of the corrosion action 45 of the main and N additional protected structures, generating a signal to output during corrosion damage of the first corrosion control element having the smallest cross section, the second corrosion action correctors 46 of the main and N additional protected structures, generating a signal at the output in case of corrosion damage of the second corrosion control element having an average cross section, the third corrosion action correctors 47 of the main and N additional protected structures, which generates a signal at the output during corrosion damage of the third element for monitoring the effect of corrosion having the largest cross section, the adder for calculating the effect of corrosion 48 of the main and N additional protected structures, integral corre Corrosion action factor by potential 49 of the main and N additional protected structures, the first timer 50 to control the entry of electric transport into the zone of protected structures, the second timer 51 to control the entry of electric transport into the zone of protected structures, the first 52 and second 53 elements "OR".

The first 22 and second 23 radio transmission units are connected to the radio reception unit 24 via a radio channel.

The first 18 sensor entry of electric transport into the area of protected structures through the first 22 radio transmission unit and radio reception unit 24 is connected via radio channel to the input of the installation in the unit "1" of the first 25 trigger, the second 21 sensor of leaving the area of protected structures by electric transport through the second 23 radio transmission unit and radio reception unit 24 connected via radio to the reset input to "0" of the first 25th trigger.

The second 19 sensor of the entry of electric transport into the area of protected structures through the second 23 radio transmission unit and the radio reception unit 24 is connected via the radio channel to the input of the installation in unit "1" of the second 26 trigger, the first 20 sensor of leaving the area of protected structures by electric transport through the first 22 radio transmission unit and the radio reception unit 24 via radio connected to the reset input to "0" of the second 26 trigger.

The output of the first 25 trigger is connected to the control inputs of the first 32 keys of the main and N additional protected structures, the first 36 corrective registers of the main and N additional protected structures and the first 29 correction key.

The output of the second trigger 26 is connected to the control inputs of the second 33 keys of the main and N additional protected structures, the second 37 corrective registers of the main and N additional protected structures and the second 30 correction key.

The outputs of the first 27 and second 28 setters correction of the protective potential through the first 29 and second 30 correction keys and the adder 31 setter connected to the corrective input of the setter potential 14 of the main protected structure.

The sensors of the protective potential 13 of the main and N additional protected structures are connected to the information inputs of the first 32 and second 33 keys of the main and N additional protected structures.

The outputs of the first 32 keys through the first 34 memory blocks of the values of the protective potentials of the main and N additional protected structures, the first 36 corrective registers for the passage of electric transport in the area of the main and N additional protected structures and the first 38 corrective amplifiers are connected to the first inputs of the correction adders 40 of the main and N additional protected structures structures.

The outputs of the second 33 keys through the second 35 memory blocks of the values of the protective potentials of the main and N additional protected structures, the second 37 corrective registers for the passage of electric transport in the zone of the main and N additional protected structures and the second 38 corrective amplifiers are connected to the second inputs of the correction adders 40 of the main and N additional protected structures structures.

The outputs of the correction adders 40 of the main and N additional protected structures are connected to the second inputs of the potential correctors 41 of the main and N additional protected structures.

The outputs of the potential correctors 41 of the main and N additional protected structures are connected to the second inputs of the comparison blocks 15 of the main and N additional protected structures.

The first corrosion action control elements 42 of the main and N additional protected structures through the first corrosion action correctors 45 of the main and N additional protected structures, which generate output signals in case of corrosion damage of the first corrosion control elements having the smallest cross section, are connected to the first inputs of the adders for calculating the corrosion action 48 main and N additional protected structures.

The second corrosion action control elements 43 of the main and N additional protected structures through the second corrosion action correctors 46 of the main and N additional protected structures, which generate output signals in case of corrosion damage of the second corrosion control elements having an average cross section, are connected to the second inputs of the adders for calculating the corrosion action 48 main and N additional protected structures.

The third corrosion control elements 44 of the main and N additional protected structures through the third corrosion action correctors 47 of the main and N additional protected structures that generate output signals in case of corrosion damage of the third corrosion control elements with the largest cross section are connected to the third inputs of the adders for calculating the corrosion action 48 main and N additional protected structures,

The common outputs of the third elements for monitoring the corrosion action 44 of the main and N additional protected structures are connected to the common inputs of the adders for calculating the corrosion action 48 of the main and N additional protected structures.

The outputs of the adders for calculating the effect of corrosion 48 of the main and N additional protected structures are connected to the second inputs of the integral correctors of the action of corrosion by potential 49 of the main and N additional protected structures.

The sensors of the protective potential 13 of the main and N additional protected structures are connected to the first inputs of the integral correctors of the action of corrosion by potential 49 of the main and N additional protected structures.

The outputs of the integral correctors of the action of corrosion on the potential 49 of the main and N additional protected structures are connected to the first inputs of the potential correctors 41 of the main and N additional protected structures.

The first 18 sensor of the entry of electric transport into the area of protected structures through the first 22 radio transmission unit and the radio reception unit 24 is connected via radio channel to the start input of the first timer 50 to control the entry of electric transport into the area of protected structures.

The second 19 sensor of the entry of electric transport into the zone of protected structures through the second 23 radio transmission unit and the radio reception unit 24 is connected via radio channel to the start input of the second 51 timer for monitoring the entry of electric transport into the zone of protected structures.

The output of the first 50 timer for controlling the entry of electric transport into the zone of protected structures through the first 52 element "OR" is connected to the reset input to "0" of the first 25 trigger,

The output of the second 51 timer control entry of electric transport in the zone of protected structures 51 through the second 53 element "OR" is connected to the reset input to "0" of the second 26 trigger.

The first 20 sensor leaving the zone of protected structures by electric transport through the first 22 radio transmission unit and the radio reception unit 24 via the radio channel, the second 53 element "OR" is connected to the reset input to "0" of the second 26 trigger.

The second 21 sensor leaving the zone of protected structures by electric transport through the second 23 radio transmission unit and the radio reception unit 24 via the radio channel, the first 52 element "OR" is connected to the reset input to "0" of the first 25 trigger.

The device works as follows.

The magnitude of the protective potential is measured directly in the zone of the protection objects of the main (O AP) and N additional protected structures (AP 1, AP N,). This ensures control of the values of protective potentials directly in the zone of the protection objects of the main and N additional protected structures. The values of potential differences between underground metal structures are measured by potential difference sensors 12 of the main and N additional protected structures. The level of protective potential is set by means of the potential generator 14 of the main protected structure.

Corrector master 16 main and N additional protected structures provides correction of the required protective potentials.

In the steady state, the values of the protective potentials of the main protected structure are set taking into account the compensation of the mutual influence of the main and additional protected structures. At the outputs of the comparison units 15 of the main and N protected structures, the voltage is zero. The values of the flowing protective currents of the main and additional protected structures are determined by the voltage levels on the integrators 9, which, through pulse-width modulators 10 and control units 11, control the power switches 5 of the main and N additional protected structures. This maintains the current value of the protective currents.

The entry of a rail electric transport into the zone of a group of protected metal underground structures is fixed by the first 18 or second 19 sensor of entry into the protection zone of the main and N additional protected structures, depending on the direction of movement of the electric transport. With the simultaneous entry of a rail electric transport into the zone of a group of protected metal underground structures from two sides, the entry is detected by both the first 18 and the second 19 sensor entering the zone of protection of metal structures.

The first 18 and second 19 sensors enter the protection zone through the first 22 and second 23 radio transmission units, the radio reception unit 24 translates the first 25 and second 26 triggers into state "1", and if the entry of rail electric transport was on one side, then one of the triggers is triggered , if on both sides, then both triggers fire. The first 25 and 26 second trigger generate the output signal "1", which opens the first 29 and second 30 correction keys. In this case, the voltage values from the first 27 and second 28 adjusters for the correction of the protective potential are summed up in the adder 31 of the setter. This correction signal is fed to the potential generator 14 of the main protected structure.

As a result, the potential generator 14 of the main protected structure is corrected. The values of the levels of correction of the first 27 and second 28 adjusters correction of the protective potential are set depending on the degree of change in electric fields from the passage of rail electric transport. When one unit of electric transport is in the zone of metal structures, the correction is made by the value of the level of the first 27 or second 28 setpoints for correcting the protective potential, when two units of electric vehicles enter from two sides, the levels of the first 27 and second 28 correction setters are summed, and the value of the signal at the output potential generator 14 increases.

The signal "1" from the first 25 and second 26 triggers also goes to the first 32 and second 33 keys of the main and N additional protected structures, which open the record of the values of protective potentials directly in the zone of the protection objects of the main (O ES) and N additional protected structures ( ZS 1, ZS N,) from the sensors of the value of the protective potential 13 in the first 34 and second 35 memory blocks of the values of the protective potentials of the main and N additional protected structures. As a result, in the first 34 blocks of memory of the values of the protective potentials of the main and N additional protected structures, a track of changes in the current values of the protective potentials during the movement of the rail electric transport, recorded by the first 18 sensor of the entry of the rail electric transport, is recorded.

Similarly, in the second 35 memory blocks of the values of the protective potentials of the main and N additional protected structures, the track of the change in the current values of the protective potentials during the movement of the rail electric transport, recorded by the second 19 sensor of the entry of the rail electric transport from the other side, is recorded. The values stored in the previous periods of movement of electric transport from the first 34 and second 35 blocks of memory of the values of the protective potentials of the main and N additional protected structures, when the next electric transport enters, are rewritten into the first 36 and second 37 corrective registers for the passage of electric transport in the zone of the main and N additional protected structures. These values through the first 38 and 39 second corrective amplifiers of the main and N additional protected structures are transmitted to the correction adders 40, and then to the second input of the potential correctors 41 of the main and N additional protected structures.

After the passage of the rail electric transport zone of the group of protected metal underground structures, the first 20 and second 21 sensors of leaving the protection zone of the main and N additional protected structures by electric transport are activated, which through the first 22 and second 23 radio transmission units and the radio reception unit 24, through the first 52 and second 53 elements "OR" reset the first 25 and second 26 triggers to the state "0" and the device goes into protection mode in the absence of electric transport.

In the event of a delay or stop of rail electric transport in the zone of a group of protected metal underground structures, the first 20 and second 21 sensors for leaving the protection zone of the main and N additional protected structures by electric transport do not work, the signal to reset the first 25 or second 26 trigger is not received, the protective potential remains in an enlarged state, which can lead to premature failure (cracking) of the waterproofing of metal underground structures.

To reset the value of the protective potential in the event of a delay or stop of rail electric transport in the zone of the group of protected metal underground structures, the first 50 and second 51 timers for controlling the entry of electric transport into the zone of protected structures are triggered and when a predetermined time has elapsed through the first 52 and second 53 elements "OR » produce a forced reset of the first 25 or second 26 trigger. The response time of the first 50 and second 51 timers is set as the maximum time for the electric transport to pass through the zone of protected underground metal structures. The first 50 and second 51 timers are launched when the electric transport enters the zone of protected structures and the first 18 or second 19 sensor is triggered with signal transmission through the first 22 or second 23 radio transmission units and the radio reception unit 24.

This achieves a decrease in the protective potential and an increase in the efficiency of cathodic protection, depending on the nature of the movement of rail electric transport in the zone of underground metal structures.

The values of the protective potential are fed to the potential difference sensors 12 of the main and N additional protected structures and through the scaling amplifiers 17 are fed to the second inputs of the correctors of the generators 16 of the main and additional protected structures, the first inputs of which are supplied with voltage from the potential generator 14 of the main protected structure, as a result of which there is a correction of the established potentials for each protected structure.

The values of the established potentials for each protected structure are compared on the comparison unit 15 of the main and additional protected structures with the values coming from the outputs of the correctors of the setters 16 and the potential correctors 41 of the main and N additional protected structures, which ensures the correction of the required protective potentials. At the output of the amplifiers 8, a corrective voltage appears, which takes the integrators 9 to another level, as a result of which the pulse-width modulators 10 through the control units 11 change the operating mode of the power switches 5 of the main and N additional protected structures.

Real-time corrosion control is performed by the first 42, second 43 and third 44 corrosion control elements of the main and N additional protected structures, made of the same material as the protected pipeline and having the smallest, average and largest section, respectively.

When the first 42 corrosion control elements are destroyed, the first 45 corrosion action correctors are triggered; when the second 43 corrosion control elements are destroyed, the second 46 corrosion action correctors are triggered; adder for calculating the effect of corrosion 48 of the main and N additional protected structures.

As a result, at the inputs of adders for calculating the effect of corrosion 48 of the main and N additional protected structures, signals for correcting corrosion protection parameters are generated depending on the magnitude of real corrosion in real time. These signals are fed to the integral corrector of the action of corrosion on the potential 49 of the main and N additional protected structures for correction of potentials by means of potential correctors 41 of the main and N additional protected structures.

Thus, an intelligent cathodic protection device with control of the corrosion process of a group of underground metal structures provides an increase in the efficiency of cathodic protection against corrosion by monitoring the magnitude of corrosion in real time and correcting the values of protective currents in the protected zone of underground metal structures from the magnitude of real corrosion and the nature of the movement of rail electric transport in their zone of passage.

Claims (1)

An intelligent cathodic protection device with control over the corrosion process of a group of underground metal structures, containing a transformer, a rectifier connected through a rectified voltage filter to the anode ground electrodes of the main and N additional metal structures, series-connected power switches, valves and filters of the main and N additional protected structures, amplifiers, integrators, pulse-width modulators and control units for power switches of the main and N additional protected structures, sensors for the potential difference of the main and N additional protected structures, sensors for the magnitude of the protective potential of the main and N additional protected structures, a potential generator for the main protected structure, blocks for comparing the main and N of additional protected structures, correctors of the generators of the main and N additional protected structures, scaling amplifiers of the main and N additional protected structures, potential generator main protected structure is connected to the first inputs of the correctors of the generators of the main and N additional protected structures, the potential difference sensors of the main and N additional protected structures are connected through the corresponding scaling amplifiers to the second inputs of the correctors of the generators of the main and N additional protected structures, respectively, the first inputs of the comparison blocks of the main and N additional protected structures, N additional protected structures are connected to the outputs of the correctors of the main and N additional protected structures, outputs with amplifiers of the main and N additional protected structures, the first and second entry sensors and the first and second sensors for leaving the protection zone of the main and N additional protected structures by electric transport, the first and second radio transmission units, radio reception unit, first and second triggers, first and second protective potential correction setters, first and second correction keys, setter adder, first and second keys chi of the main and N additional protected structures, the first and second memory blocks of the values of the protective potentials of the main and N additional protected structures, the first and second corrective registers for the passage of electric transport in the zone of the main and N additional protected structures, the first and second corrective amplifiers of the main and N additional protected structures , correction adders of the main and N additional protected structures, potential correctors of the main and N additional protected structures, the first and second radio transmission units are connected to the radio reception unit via a radio channel, the first sensor of electric transport entering the zone of protected structures through the first radio transmission unit and the radio reception unit via a radio channel is connected to by the input of the installation to the unit "1" of the first trigger, the second sensor of the entry of electric transport into the zone of protected structures through the second radio transmission unit and the radio reception unit via the radio channel is connected to the input of the installation to the unit "1" of the second of the trigger, the output of the first trigger is connected to the control inputs of the first keys of the main and N additional protected structures, the first corrective registers of the main and N additional protected structures and the first correction key, the output of the second trigger is connected to the control inputs of the second keys of the main and N additional protected structures, the second corrective registers of the main and N additional protected structures and the second correction key, the outputs of the first and second generators for correcting the protective potential through the first and second correction keys and the generator adder are connected to the correction input of the potential generator of the main protected structure, the sensors of the protective potential of the main and N additional protected structures connected to the information inputs of the first and second keys of the main and N additional protected structures, the outputs of the first keys through the first memory blocks of the values of the protective potentials of the main and N additional protections of the protected structures, the first corrective registers for the passage of electric transport in the zone of the main and N additional protected structures and the first corrective amplifiers are connected to the first inputs of the correction adders of the main and N additional protected structures, the outputs of the second keys through the second memory blocks of the values of the protective potentials of the main and N additional protected structures, the second corrective registers for the passage of electric transport in the zone of the main and N additional protected structures and the second corrective amplifiers are connected to the second inputs of the correction adders of the main and N additional protected structures, the outputs of the correction adders are connected to the second inputs of the potential correctors of the main and N additional protected structures, the outputs of the potential correctors are connected with the second inputs of the comparison blocks of the main and N additional protected structures, characterized in that it additionally introduced the first control elements of the action i corrosion of the main and N additional protected structures, made of the same material as the protected pipeline, and having the smallest cross section, the second corrosion control elements of the main and N additional protected structures, made of the same material as the protected pipeline, and having an average cross section , third elements for monitoring the corrosion effect of the main and N additional protected structures, made of the same material as the protected pipeline and having the largest cross section, the first correctors for the corrosion action of the main and N additional protected structures, generating an output signal in case of corrosion failure of the first action control element corrosion, having the smallest cross section, the second correctors of the corrosion action of the main and N additional protected structures, generating an output signal in case of corrosion destruction of the second element for controlling the corrosion action, having an average cross section, the third correctors of the action of corrosion ii of the main and N additional protected structures, generating a signal at the output in case of corrosion damage of the third corrosion control element having the largest cross section, adders for calculating the corrosion action of the main and N additional protected structures, integral correctors of the corrosion action by the potential of the main and N additional protected structures, the first and the second timers for controlling the entry of electric transport into the zone of protected structures, the first and second "OR" elements, and the first elements for controlling the effect of corrosion of the main and N additional protected structures through the first correctors for the effect of corrosion of the main and N additional protected structures, generating signals at the output during corrosion destruction the first corrosion control elements having the smallest cross section are connected to the first inputs of the adders for calculating the corrosion effect of the main and N additional protected structures, the second corrosion control elements of the main and N additional protected structures through the second correctors of the corrosion action of the main and N additional protected structures, generating signals at the output during corrosion damage of the second corrosion action control elements having an average cross section, are connected to the second inputs of the adders for calculating the corrosion action of the main and N additional protected structures, the third corrosion control elements of the main and N additional protected structures through the third corrosion action correctors of the main and N additional protected structures, which generate output signals in case of corrosion damage of the third corrosion control elements having the largest cross section, are connected to the third inputs of the adders for calculating the corrosion action of the main and N additional protected structures, the common outputs of the third elements for monitoring the corrosion action of the main and N additional protected structures are connected to the common inputs of the adders for calculating the action of cor the main and N additional protected structures, the outputs of the adders for calculating the corrosion effect of the main and N additional protected structures are connected to the second inputs of the integral correctors of the corrosion action according to the potential of the main and N additional protected structures, the sensors of the protective potential of the main and N additional protected structures are connected to the first inputs integral cor- rosion action correctors according to the potential of the main and N additional protected structures, the outputs of which are connected to the first inputs of the potential correctors of the main and N additional protected structures, the first sensor of the entry of electric transport into the zone of the protected structures through the first radio transmission unit and the radio reception unit via the radio channel is connected to the launch input of the first a timer for controlling the entry of electric transport into the zone of protected structures, the second sensor for the entry of electric transport into the zone of protected structures through the second radio transmission unit and the radio transmission unit It is connected via radio channel to the start input of the second timer to control the entry of electric transport into the zone of protected structures, the output of the first timer to control the entry of electric transport into the zone of protected structures through the first element "OR" is connected to the reset input to "0" of the first trigger, the output of the second timer to control the entry of electric transport to the zone of protected structures through the second element "OR" is connected to the reset input to "0" of the second trigger, the first sensor for leaving the zone of protected structures by electric transport through the first radio transmission unit and the radio reception unit via the radio channel, the second element "OR" is connected to the reset input to "0" » of the second trigger, the second sensor for leaving the zone of protected structures by electric transport through the second radio transmission unit and the radio reception unit via the radio channel, the first "OR" element is connected to the reset input to "0" of the first trigger.

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