RU2491373C1 - Adaptive device of cathode protection from corrosion of group of underground metal structures - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: device comprises a transformer, a rectifier, power switches, valves and filters of the main and N additional protected structures, amplifiers, integrators, pulse-width modulators and units of power switches control of the main and N additional protected structures, a sensor of potential difference of the main and N additional protected structures, a sensor of protective potential value of the main protected structure, a setter of potential of the main protected structure, a unit of comparison of the main protected structure, N sensors of protective potential value of additional protected structures, a corrector of the setter of the main protected structure, N correctors of the setter of additional protected structures, N units of comparison of additional protected structures, a scaling amplifier of the main protected structure and N scaling amplifiers of additional protected structures.

EFFECT: using the invention makes it possible to increase efficiency of cathode protection in case of exposure to external electric fields.

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Description

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

A known scheme of cathodic protection of underground metal structures, including the protected structure, an adjustable direct current source, connecting wire and anode grounding (Corrosion protection of pipelines and tanks. Textbook. - M .: Nedra, 1978. Authors: Dizenko EI, Novoselov V .F., Tugunov P.I., Yufin V.A., p.113-117). In this device, the negative pole of the DC source is connected to the protected structure, the positive pole to the artificially created anode - ground electrode.

This protection scheme is most suitable for single pipelines and structures.

If it is necessary to protect several pipelines of various affiliation, purpose, insulation, parameters located in soil or water electrolytes, perform direct or valve jumpers, carry out joint protection of underground structures (Instruction for the protection of urban underground pipelines from electrochemical corrosion. - M .: Stroyizdat, 1974, p. 86-89; 1982, p. 74-79). Such a cathodic protection system can be carried out by connecting various structures to a common protective installation with the simultaneous installation of metal connections between individual structures.

When developing a joint protection scheme in branched networks of underground structures, the main structure is chosen - the main drainage circuit, to which the remaining protected structures are connected with jumpers. The joint protection system of underground structures for various purposes includes: protected metal structures - pipelines, adjustable jumpers, direct current source - adjustable rectifier, anode grounding.

With this joint protection, the various structures, foundations, insulation, and parameters of structures located in soil or water electrolytes turn out to be galvanically connected to each other. Since the stationary potentials of the protected structures are different, when they are connected to each other, both direct and valve jumpers, a powerful galvanic corrosion pair is formed, which it is not always possible to “suppress” with the help of a direct current source in the range of polarization potentials recommended by the current GOST. Moreover, under such conditions, it is difficult to measure the potentials of individual structures at the drainage point, and the direct current source - an adjustable rectifier itself becomes a source of stray currents.

When regulating a direct current source, the potentials of structures, the stationary potentials of which were different before connecting the jumpers, acquire different polarization potentials and cannot be compensated within the limits recommended by GOST.

Thus, the joint protection of two or more pipelines and underground metal structures by a single source of direct current is not effective.

A device for the joint cathodic protection of underground structures (Pat. SU No. 524860, C23F 13/00, 1976), which contains an adjustable rectifier, the positive terminal of which is connected to the anode ground.

The disadvantage of this device is the lack of effectiveness of joint cathodic protection.

A known system of cathodic protection of two or more structures (Pat. RU No. 2151218, C23F 13/02, 2003), which contains a transformer, rectifier, the positive terminal of which is connected to the anode ground electrode, two silicon valves, two adjustable resistance, and the negative terminal rectifier connected to a common point interconnected cathodes of silicon valves, the anodes of which are connected to each of the protected structures through adjustable ballast resistances.

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 of a group of underground metal structures (Pat. RU No. 2394943, C23F 13/02, 2010), consisting of the main and additional metal structures, containing a transformer, rectifier, silicon valves in the circuit of the protected structures, a protective value sensor potential of the main protected structure, potential difference sensors of additional protected structures, power switches and filters of the main and additional protected structure,

A disadvantage of the known device is the low efficiency of cathodic protection, the lack of adaptability to the effects of external electric fields.

Closest to the invention is an adaptive cathodic corrosion protection device for a group of underground metal structures (Pat. RU No. 2440442, C23F 13/02, 2012), consisting of a main and additional metal structures and containing a transformer, a rectifier, whose positive terminal is through a filter the rectified voltage is connected to the anode ground electrode, serially connected power switches, valves and filters of the main and N additional protected structures, amplifiers, integrators, pulse-width modulators and Loka power switches control the main and additional N protected structures, the sensor potential difference of the main and additional N protected structures, the sensor value of the protective capacity of the protected primary structures, building ground dial protected structures, the block comparison protected basic structure.

A disadvantage of the known prototype is the low efficiency of cathodic protection against corrosion of a group of underground metal structures during unsteady exposure to external electric fields in the soil from various sources.

The objective of the invention is to increase the effectiveness of cathodic protection against corrosion of a group of underground metal structures by compensating for the unsteady effect of external electric fields in the soil from various sources by measuring and correcting protective potentials directly in the zone of protection objects.

This goal is achieved by the fact that in an adaptive cathodic corrosion protection device of a group of underground metal structures, consisting of a main and additional metal structures, containing a transformer, a rectifier, the positive terminal of which is connected to the anode ground electrode through a rectified voltage filter, power switches, valves and filters of the main and N additional protected structures, amplifiers, integrators, pulse-width modulators and power control units with the keys of the main and N additional protected structures, the potential difference sensor of the main and N additional protected structures, the protective potential value sensor of the main protected structure, the potential protected building main capacity sensor, the main protected structure comparison unit, N additional protective potential value sensors of the additional protected structures are introduced, corrector setter of the main protected structure, N correctors of the setter of additional protected structures, N b locks for comparison of additional protected structures, a scaling amplifier of the main protected structure and N scaling amplifiers of the additional protected structures, the potential master of the main protected structure being connected to the first inputs of the corrector of the master of the main protected structure and N corrector of the master of the additional protected structures, the potential difference sensor of the main and N difference sensors potentials of additional protected structures through appropriate scaling amplifiers of the main protected structure and N scaling amplifiers of additional protected structures are connected to the second inputs of the master corrector of the main protected structure, and N corrector corrections of the additional protected structures, respectively, the first input of the comparison unit of the main protected structure is connected to the output of the master corrector of the main protected structure, and the second input is connected to a sensor of the value of the protective potential of the main protected structure, the first inputs of N blocks eniya additional protected facilities are connected to the N outputs of the correctors setpoint additional protected structures, and second inputs connected to the N sensor values protective potential additional protected structures, the comparator outputs the main and additional N comparators protected facilities are connected to the main amplifier and N additional protected structures.

The figure shows a diagram of an adaptive device for cathodic protection against corrosion of a group of underground metal structures.

The device contains a transformer 1, a rectifier 2, a rectified voltage filter 3, an anode ground electrode 4, serially connected power switches 5, valves 6 and filters 7 of the main and N additional protected structures, amplifiers 8, integrators 9, pulse-width modulators 10 and control units 11 with power keys of the main and N additional protected structures, the potential difference sensor 12 of the main and N additional protected structures, the sensor of the protective potential value 13 of the main protected structure, 14 of the main protected structure, comparison unit 15 of the main protected structure, N sensors of the protective potential value 16 additional protected structures, master corrector 17 of the main protected structure, N master corrector 18 additional protected structures, N comparison blocks 19 additional protected structures, scaling amplifier of the main protected structures and N scalable amplifiers 20 additional protected structures.

Adaptive cathodic protection against corrosion of a group of underground metal structures works as follows.

The value of the protective potential is measured directly in the zone of the protection of the main (О ЗС) and N additional protected structures (ЗС 1, ЗС N,) by means of the sensor of the value of the protective potential 13 of the main protected structure and N sensors of the value of the protective potential of 16 additional protected structures. This ensures control of the values of protective potentials directly in the area of the protection objects of the main and N additional protected structures.

The 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 a potential adjuster 14 of the main protected structure,

The corrector of the master 17 of the main protected structure, N corrector of the master 18 of the additional protected structures provides the correction of the required protective potentials to compensate for the mutual influence of the main and additional protected structures.

In the steady state, the values of the protective potentials of the main protected structure are established by an adaptive cathodic corrosion protection device for a group of underground metal structures, taking into account the compensation of the mutual influence of the main and additional protected structures. At the outputs of the comparison blocks 15 of the main protected structure and N comparison blocks of 19 additional 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 at 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.

Under the influence of external electric fields in the soil from various sufficiently powerful sources (tram and railway tracks, transformer substations) located in the zone of the group of protected metal underground structures, the potential difference at the main and additional protected structures changes.

These values are recorded by potential difference sensors 12 of the main and N additional protected structures and, through scaling amplifiers 20, are supplied to the corrector of the master 17 of the main protected structure, N correctors of the master 18 of the additional protected structures. At the same time, voltage is supplied from the potential adjuster 14 of the main protected structure to the first inputs of the corrector of the master 17 of the main protected structure and N corrector of the master 18 of the additional protected structures, as a result of which the installed potentials are corrected for each protected structure.

The adjusted values of the installed potentials for each protected structure are compared on the comparison unit 15 of the main protected structure and N comparison blocks of 19 additional protected structures with the values received from the protective potential value sensor 13 of the main protected structure and N protective potential value sensors 16 of the additional protected structures. In the event of a mismatch at the output of the amplifiers 8, a corrective voltage appears, which transfers the integrators 9 to another level, as a result of which pulse-width modulators 10, through the control units 11, change the operation mode of the power switches 5 of the main and N additional protected structures. Using the scaling amplifier of the main protected structure and N scaling amplifiers 20 of the additional protected structures, the level of influence of the potential difference sensors 12 on the corrector of the master 17 of the main protected structure, N correctors of the master 18 of the additional protected structures is established. This achieves the development of external effects of electric fields in the soil from various sufficiently powerful sources located in the zone of the group of protected metal underground structures.

Thus, an adaptive cathodic corrosion protection device for a group of underground metal structures provides an increase in the efficiency of cathodic corrosion protection for a group of underground metal structures by compensating for the unsteady effect of external electric fields in the soil from various sources by measuring and correcting protective potentials directly in the zone of protection objects.

Claims (1)

An adaptive cathodic corrosion protection device for a group of underground metal structures, consisting of a main and N additional metal structures, containing a transformer, a rectifier, the positive terminal of which is connected to the anode ground electrode through a rectified voltage filter, power switches, valves and filters of the main and N additional protected structures, amplifiers, integrators, pulse-width modulators and control units for power keys of the main and N additional protection buildings, the potential difference sensor of the main and N additional protected structures, the sensor of the protective potential value of the main protected structure, the potential controller of the main protected structure, the comparison unit of the main protected structure, characterized in that N sensors of the protective potential value of the additional protected structures are additionally introduced into it, corrector of the master of the main protected structure, N correctors of the master of the additional protected structures, N blocks compared additional protected structures, a scaling amplifier of the main protected structure and N scaling amplifiers of the additional protected structures, the potential master of the main protected structure being connected to the first inputs of the corrector of the master of the main protected structure and N corrector of the master of the additional protected structures, the potential difference sensor of the main and N potential difference sensors additional protected structures through appropriate scaling amplifiers about the main protected structure and N scaling amplifiers of the additional protected structures are connected to the second inputs of the master corrector of the main protected structure, and N corrector corrections of the additional protected structures, respectively, while the first input of the comparison unit of the main protected structure is connected to the output of the master corrector of the main protected structure, and the second input is connected with a sensor of the value of the protective potential of the main protected structure, and the first inputs of N blocks with avneniya additional protected facilities are connected to the N outputs of the correctors setpoint additional protected structures, and second inputs connected to the N sensor values protective potential additional protected structures, the comparator outputs the main and additional N comparators protected facilities are connected to the main amplifier and N additional protected structures.

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