RU2584834C2 - Method for combined protection of metal structures from lightning discharges and electrochemical corrosion - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to protection of metal structures against electrochemical corrosion and lightning discharges. Method involves use of cathodic protection against corrosion, containing DC source and graphitized carbon anodic grounding, lightning protection system containing lightning rod and current collector, by means of contact device and steel comparison electrode, wherein the graphitized carbon anodic grounding of cathodic protection system is used as grounding circuit of lightning protection, operation modes “without lighting storm" and "lighting storm" are set, cathode polarization of metal objects in continuous mode, and lightning discharge mode is connected to cathodic protection system during period of lightning discharges risk, wherein removal of lightning discharges from protected object by guidance system of lightning protection of positive electrochemical potential, value of which does not exceed 90 in relation to steel comparison electrode.

EFFECT: technical result is provision of safety of production facilities against lightning discharges, prevention of corrosion destruction elements lightning protection, protected constructions and underground pipelines.

1 cl, 3 dwg, 3 tbl

Description

The present invention relates to the field of the science of electrical engineering and electrochemistry, in particular to active systems for protecting industrial buildings, structures, private residential buildings from the effects of atmospheric electricity discharges, and systems for protecting steel underground structures from electrochemical corrosion.

The present invention considers a method of lightning protection of special objects with limited danger to the immediate environment, such as oil and gas refineries, gas stations, storage facilities for liquefied petroleum gas and the like, for which an acceptable level of reliability from direct lightning strikes is set in the range from 0.9 to 0.999 depending on the degree of social significance and the severity of the expected consequences of lightning strikes.

The currently known method of lightning protection, as the most traditional way of protection, is regulated in Russia by the instruction approved by order of the Ministry of Energy of the Russian Federation on June 30, 2003 No. 280 “Instructions for the installation of lightning protection of buildings, structures and industrial communications”. Lightning protection devices are used to protect all types of buildings, structures and industrial communications, regardless of departmental affiliation and form of ownership and their application is based on the provision that any device cannot prevent the development of lightning, and its use reduces the risk of damage from lightning strikes. The complex of lightning protection devices includes devices from direct lightning strikes related to the external lightning protection system, and devices for protection against secondary effects of lightning related to the internal lightning protection system. External devices from direct lightning strikes - lightning rods, are a complex consisting of lightning receivers, down conductors and grounding conductors.

The air terminal is designed to intercept lightning. Lightning currents falling into the air terminal, through a system of down conductors (descents) are diverted to the ground electrode and spread in the ground. For elements of an external lightning protection system, steel, aluminum, and copper are used, which have a certain natural (stationary) potential.

Specially installed lightning rods consist of an arbitrary combination of elements: individual rods, tensioned wires (cables), mesh conductors (grids), or their functions are performed by natural lightning rods (metal roofs of protected objects, metal roof structures, metal elements of downpipes, technological metal pipes and tanks )

The down conductors are located so that between the point of destruction and the ground, the current spreads along several parallel paths and the length of these paths should be limited to a minimum. In lightning protection devices isolated from the protected object: a rod lightning rod mounted on a support provides at least one down conductor, a cable lightning rod at each end of the cable has one down conductor, and a mesh design for at least one down conductor for its support. With non-insulated devices, down conductors are located along the perimeter of the building with a distance depending on the level of protection. Natural down conductors are metal structural elements of buildings (structures, frame of a building or structure, steel reinforcement, parts of the facade).

Earthing switches, for general reasons, with the exception of a separate lightning rod, are combined with earthing switches of electrical installations and communications. If, for any technological reasons, grounding conductors should be separated, a potential equalization system is used. The depth of the laying and the type of grounding devices are selected from the condition of ensuring minimal corrosion, as well as possibly the smallest seasonal variation in grounding resistance as a result of drying and freezing of the soil. Interconnected reinforced concrete reinforcement or other underground metal structures are used as natural grounding electrodes.

The system of protection against direct lightning strikes is selected so as to maximize the use of natural lightning rods, and to ensure reliability - in combination with specially installed ones.

According to the recommendations of IEC (IEC 1024-1-1), the practical feasibility of methods for determining protection zones is as follows:

- for structures of simple form - the protective angle method;

- for complex structures - the fictitious sphere method;

- for surfaces - a protective mesh method.

In the system of the invention, a rod lightning rod is used and the protection zone is determined according to standard rules. The standard lightning protection zone of a single rod lightning rod is a circular cone, the top of which coincides with the vertical axis of the lightning rod. The dimensions of the zone are determined by two parameters: the height of the cone (ho) and the radius of the cone at ground level (ro). For the reliability level (Рз) = 0.999 and for lightning conductors with a height (h) of up to 150 m, the zone calculation is determined by the formulas listed in table 1.

Table 1 Lightning rod height, h (meter) Ho cone height (meters) Radius of cone rо (meters) 0 to 30 0.7h 0.6h 30 to 100 [0.7-7.14 × 10 ^-4 × (h-30)] × h [0.6-1.43 × 10 ^-3 × (h-30)] × h 100 to 150 [0.65-10 ^-3 × (h-100)] × h [0.5-2 × 10 ^-3 × (h-100)] × h

The disadvantage of the above prototype is the following:

1. Due to the large current strength and the steepness of its growth during a lightning strike, a much larger potential difference arises than due to current leakage in a three-phase circuit. Therefore, to protect against the effects of lightning currents, a potential equalization system is used, for this purpose directly or indirectly connect electrical installations, metal accessories, grounding system and lightning protection system with protection devices via the equalization bus. The goal of potential equalization is to ensure equal potentials in all interconnected metal elements of the object, that is, to create an equipotential surface. Then, when a high potential is drifted inside the object, it simultaneously rises on all metal structures, due to which a dangerous potential difference does not arise, the possibility of dangerous currents and sparking flowing is excluded.

However, the existing potential equalization system does not fully fulfill its purpose, since the value of the natural electrochemical (stationary) potential of the material from which the lightning protection elements are made is not taken into account. Between lightning protection elements and an underground structure (for example, storage tanks for liquefied gas), a corrosive macropair is formed. Typically, for the manufacture of external lightning protection elements, the materials listed in table 2 are used.

table 2 Material Stationary potential (volt) Section (mm sq.) Air terminal down conductor earthing switch Steel -0.55 fifty fifty 80 Aluminum -0.75 70 25 not applicable Copper +0.35 35 16 fifty

Considering structures for storing explosive substances (underground steel tanks, tanks for storing gas, gasoline, etc.) and when executing the grounding circuit of lightning protection made of copper, a corrosion macro-couple is formed in which the structure acts as a destructive electrode. Macropairs contribute to the formation of through corrosion caverns through which hazardous substances leak into the environment. Such electrical connections are prohibited by regulatory documents that regulate the processes of electrochemical corrosion and protection during the operation of industrially hazardous production facilities, such as steel underground tanks for storing liquefied gas, gasoline, cabinet gas control points with steel gas pipelines.

In the case of directing a positive or negative potential on an electrical device from an external current source on the ground loop, an induced potential also appears on the air terminal. In such a situation, the lightning protection system does not fulfill its design functions, and the protected structure will act as an air terminal, since on its ground loop the potential is larger in magnitude than on the ground loop of a lightning rod.

2. Elements of the lightning protection system made of steel or aluminum have a corresponding natural stationary negative potential. By their nature, most lightning, about 90%, also have a negative current discharge. According to the known laws of physics, negative charges repel, therefore, the considered system of lightning protection does not fulfill the physical function of intercepting lightning.

3. Steel grounding electrodes used in most cases are oxidized in a ground electrolyte, that is, corrosion vapors are formed on the electrodes and they are coated with corrosion products. Corrosion products in the form of rust are not conductive. The spreading resistance of the steel ground loop relative to time and soil resistivity worsen the functional operation of lightning protection, since the spreading resistance of the grounding grounding loop contour increases. The way to combat corrosion of the underground elements of the system is only to replace them while reducing their cross-sectional area by more than 25%.

4. The regulations for the operation of the lightning protection system provide for a visual inspection of the integrity of the system before the start of the thunderstorm season and is limited to 20% of their total number. For the most part, this lightning protection system is a passive, non-regulated protection system.

Technical solutions regarding the method of protecting steel underground structures from electrochemical corrosion, and methods for monitoring the effectiveness of the applied protection are embodied in the Interstate standard GOST 9.602-2005 “Unified system of protection against corrosion and aging. Underground facilities ”(developed by the State Unitary Enterprise Academy of Public Utilities named after KD Pamfilov, State Unitary Enterprise VNII railway transport, FSUE VNIIstandard (hereinafter GOST 9.602-2005), which was put into effect by order of the Federal Agency for Technical Regulation and Metrology of 10.25.2005 No. 262-st.), in the working documentation RD 153-39.4-091-01 “Instructions for the Protection of Urban Underground Pipelines from Corrosion” (approved by the Ministry of Energy of the Russian Federation on December 29, 2001). Currently, the application of these regulatory documents is mandatory in connection with the classification of protected facilities as hazardous production facilities.

The technical essence of the known method of electrochemical protection lies in cathodic polarization using an external current source. As an electrical protection installation (hereinafter referred to as EZU), a cathode converter is used, which is an external source of direct current and serves to guide the electrochemical potential. The negative pole of the EZU through the drain cable through the contact device on the pipeline is connected to the protected pipeline, the positive pole of the EZU through the drain cable is connected to the anode ground. As anode grounding, grounding conductors are usually used that have sufficient resistance to electrolytic dissolution, for example, grounding conductors made of carbon graphite, iron-silicon, and cast iron. Anode grounding is designed to provide a cathode current structure. The cathodic polarization protects the underground structure provided that the protective potential of the metal (for steel) relative to the saturated copper-sulfate reference electrode is between the minimum from minus 0.90 volts and the maximum to minus 2.5 volts.

The closest analogue to the invention is a device for protecting metal structures from corrosion with a lightning protection device (patent SU 177095 A1, C23A 13/00, publ. 09/15/1991). The device is designed to improve reliability and is equipped with two control short circuits, a lightning indicator, a delay unit and a diode, while the contacts of the first short circuit are connected to the input of the cathode station, and the second to its output, the control inputs of both short circuits are connected and connected to the output of the delay unit , the input of which is connected to the output of the lightning activity indicator and the control input of the managed switch, and the diode is included in the output circuit of the cathode station between the positive th terminal and an anode grounded.

Patent RU 2223346 C1, C23A 13/04, publ. 02/10/2004, The pulse current protection device is designed to increase the efficiency of cathodic protection and contains an electronic unit with a direct current source, is connected through a pulse amplifier to the protected structure and to the grounding device, the measuring electrodes are connected to the pulse generating circuit of the electronic unit, the output of which is connected At the input of the pulse amplifier, between the DC source and the pulse amplifier, a charger and an energy storage device are installed. The device allows to obtain pulses of significantly longer duration and to protect extended sections of the pipeline. To prevent the destruction of the electronic unit when lightning strikes the electric network, a lightning protection device is installed at the entrance to the direct current source.

The considered devices have the same features as the invention, namely, the use of a cathode converter, grounding devices for cathodic polarization of the protected structure and a lightning protection device in order to protect the cathode converter from lightning. A disadvantage of the described devices is that the lightning protection device does not perform the functions of an active trap of lightning discharges to protect the metal structure itself, but performs only a passive function of protecting the cathode converter from lightning damage.

The basis of the invention is the task of creating a method that ensures the reliability of lightning protection of metal objects for various purposes by sharing lightning protection elements and cathodic protection to trap and discharge lightning discharges and at the same time protect metal structures from electrochemical corrosion.

Accordingly, the technical result achieved by the implementation of the proposed method:

1. Its use in hazardous production facilities is to ensure their safety from lightning discharges, to prevent corrosion damage to elements of the lightning protection system and at the same time to protect structures and underground pipelines from them from electrochemical corrosion. The claimed method is proposed to be applied at the following facilities:

- steel tanks for storing liquefied gas, oil products and other explosive liquids and gases at industrial sites and installed in the ground or dipped in soil;

- tanks for storing liquefied gas and gasoline at gas stations, installed in the ground or dipped in soil;

- freestanding gas control points;

- other free-standing premises with supplying underground facilities (heating mains, steel pipelines, steel gas pipelines).

2. Application in the private sector for buildings, cottages and facilities with outdoor television and radio receivers and underground steel communications.

The relevance lies in the safety of television and radio devices, computers and other household appliances located in the premises from lightning damage, and possibly from fire. Television and radio receiving antennas have a small but positive potential relative to the ground, and the currently used grounding devices made of steel have a negative potential relative to the ground using a copper-sulfate reference electrode. A thunderstorm discharge, which in most cases has a negative charge, strikes television and radio antennas, which leads to the failure of household appliances. An air terminal and a ground loop having a positive potential relative to the ground will help to eliminate the danger of a lightning strike in the television and radio antennas, since the positively charged value of the potential of the air terminal and the ground loop is higher in absolute value compared to the potential of the receiving television and radio antenna.

The problem is solved by the implementation of a comprehensive protection system, consisting in the use of known devices used to protect against lightning strikes according to the order of the Ministry of Energy of the Russian Federation No. 280 dated 06/30/2003, "Instructions for lightning protection devices of buildings, structures and industrial communications" and used for electrochemical protection of underground communications in accordance with the current international standard GOST 9.602-2005 "Unified system of protection against corrosion and aging" and is characterized by the following essential features:

combining a cathodic protection system against electrochemical corrosion, containing a direct current source similar to a cathode converter and carbon graphite anode grounding, with a lightning protection system containing a rod lightning rod and a down conductor, using a contact device and a steel reference electrode, while carbon graphite anode grounding of the cathodic protection system is used in outline quality;

grounding of lightning protection, the direct current source provides two operating modes: “thunder-free mode” and “thunderstorm mode”, and the cathodic polarization of the protected structure is provided in continuous mode, and the lightning protection mode, that is, “thunderstorm mode”, is connected to the cathodic protection system in times of danger lightning discharges, while the discharge of lightning discharges from the protected structure is ensured by pointing at the lightning protection system a positive electrochemical potential, the value of which does not exceed 90 volts, relates steel ceiling elements reference electrode.

Distinctive features of the claimed method (device) in comparison with the closest analogue is the following:

1. It more effectively performs the role of lightning protection, since a lightning rod and lightning protection grounding conductors have induced (artificially created) positive electrochemical potential relative to the ground, by using an external DC source and using anode grounding of the cathodic protection system as a grounding circuit for lightning protection. The modes of the cathode converter make it possible to achieve a more positive potential with respect to the ground electrolyte, of the order of 90 volts in the system “air terminal - lightning protection circuit”.

2. The electrochemical potential in the system under consideration can be controlled by the output parameters of the cathode converter relative to the area of the protected object, the number of lightning rod installations with anode ground loops used and taking into account the specific resistance of the soil at the location of the object, which are taken into account in the corresponding project regarding the resistance to spreading of the anode ground, the number of electrodes for cathodic current systems to obtain effective electrochemical protection for the subbase a lot of construction.

The effectiveness of protection is determined by the total or polarization potential. The calculated parameters of the electrochemical protection system are defined in RD No. 153-39.4091-01 “Protection of urban underground pipelines from corrosion”. As a rule, when performing the calculated parameters of the electrochemical protection system to characterize the anode grounding in order to obtain a protective cathode current, the resistance to anode ground spreading from 2 to 5 ohms. During operation of the anode grounding, the resistance to spreading increases and if it exceeds about 10-15 Ohms, the anode grounding is subject to modernization or major repairs. However, such standard values of the resistance to spreading of the anode ground, which in the proposed method simultaneously acts as a lightning protection circuit, are much lower than those (of the order of 40 Ohms) that are presented to existing lightning protection systems.

3. Steel electrodes of the ground loop used in traditional lightning protection devices have been replaced by carbon-graphite electrodes, which are currently used in the system of electrochemical protection of underground utilities from electrochemical corrosion (gas pipelines, oil pipelines). Unlike steel ground electrodes, which are oxidized and have a stationary potential (-0.55 V), carbon graphite electrodes are not susceptible to oxidation, have a positive potential, sufficient resistance to electrolytic dissolution in a ground electrolyte, and are less expensive in construction and overhaul .

4. Maintenance of the anode ground loop, which acts as a grounding conductor of lightning protection, according to the instruction manual for electrochemical protection systems, is carried out more competently technologically using appropriate devices, since the resistance to spreading of the anode ground in electrochemical protection systems plays the main role in obtaining a protective cathode current and effective protective potential in the underground structure.

5. The application of the claimed method will allow you to regulate the effective use of the lightning protection system, that is, in a timely manner during a thunderstorm threat to regulate the technical parameters of the system. The operation mode of the lightning protection system during a thunderstorm should be regulated relative to the increase in the positive potential on the lightning rod and the ground loop, while maintaining the required cathode current and the value of the effective protective potential on the protected underground structure using additional control resistance in the circuit "electrical protection installation - contact device on the protected structure", as shown in figure 1. At the same time, switching to the "thunderstorm" mode should be carried out as in a machine both manual and manual.

6. Aiming of the positive electric potential on the air terminal and the ground loop contributes to the target compulsory capture of negatively charged lightning discharges, since oppositely charged particles are attracted to each other.

7. The presence of a positive potential on the air terminal and the ground loop contributes to the forced removal of positively charged lightning charges from the protected structure, since particles of the same name repel each other.

8. Obtaining a negative potential at the protected structure provides cathodic polarization of the underground metal structure, which is an additional effective factor in the removal of a lightning discharge from the protected structure to the lightning rod.

The implementation of the claimed method is as follows.

The connection diagram of the installation for protection against lightning discharges and electrochemical corrosion is shown in FIG. 1. The following elements are used in the system:

- The air terminal 1 is used to receive free electrons. It is a core element. Use the height and design of the air terminal according to the “Instructions for the installation of lightning protection for buildings, structures and industrial communications” (Order of the Ministry of Energy of the Russian Federation No. 280 of 06/30/2003).

- Down conductor 2 serves to direct lightning. An AVVG brand cable with the cross-section indicated in table 2 is used.

- Anode grounding 3, as an element of cathodic protection, simultaneously serves as a grounding conductor for lightning protection and serves to safely dissipate the lightning current in the ground. The dependence of the number of electrodes on the resistivity of the soil and the cathodic current required for the effective cathodic polarization of an underground structure for one installation is presented in table 3.

- The cathode converter 4 represents an external DC source and serves to guide the electrochemical potential.

- Automatic protection against overvoltage 12 is necessary so that when lightning enters the air terminal, all current is forced to drain into the ground through earthing switches, and the cathode converter, having fulfilled its role, is switched off to prevent failure.

- The control resistance is a diode-resistor unit 6, serves to further control the resistance and cathode current in the circuit of the electrochemical protection system.

- Contact device 7 for connecting the elements of the system "cathode converter - anode grounding - air terminal" and control the efficiency of the system.

- Access to the power supply network is assumed from the support of the power line 8.

- Protected steel structure 9.

- Long-acting copper-sulfate reference electrode 11 and a steel reference electrode 13 for performing measurements of monitoring the system’s performance.

- Circuit breaker 5.

- Lightning protection zone 15.

- Drainage cable cathodic protection 16 brand AVVG.

The method of joint protection of steel structures from lightning discharges and electrochemical corrosion using an installation for protection against lightning discharges and electrochemical corrosion is as follows.

The cathode converter 4 is installed on a pedestal, power is supplied from the 8.15 power supply network with a voltage of 220 volts. The location of the cathode converter is determined in the plan on the ground according to the developed project. Connect the positive terminal of the cathode converter 4 through an automatic overvoltage protection device 12 with cable 2 (material aluminum, AVVG brand, cable cross-section is selected according to table 2) with the anode ground loop 3 in contact device 7. In contact device 7, connect the anode ground 3 with cable 2 (material aluminum, AVVG brand, cable cross-section is selected based on the required protective current) with an air terminal 1. Connect the cable to the air terminal above the ground, above the level of snow cover in depending on the usual winter conditions of the respective region. Connect the negative terminal of the cathode converter 4 through the control resistance 6 to the underground structure 9 (steel gas storage tank) in the contact device 14 with cable 2 (aluminum material, AVVG grade, cable cross-section is selected based on the required protective current). In the system "cathode converter 4 - protected building 9" to perform separate ground loops from the drift of high voltage. To measure the required value of the protective potential on the protected structure in the contact device 14, install a copper-sulfate reference electrode (MSED), to measure the positive potential required to perform the effective function of lightning protection, install a steel reference electrode (SES) in the contact device 7. The value of the electrochemical potential on the protected structure and anode grounding to establish during commissioning. For the effective operation of the anode grounding, set two modes: “thunder-free mode”, “thunderstorm mode”. To ensure cathodic polarization of steel underground structures, the cathodic protection system operates in a continuous mode. The normative value of the protective potential at the protected structure should be applied in accordance with the Interstate Standard GOST 9.602-2005 “Unified system of protection against corrosion and aging” when the system is operated in the “no thunder” and “thunder” modes. Lightning removal mode is connected to the protection system during the period of danger of lightning discharges. In the "thunderstorm" mode, the potential value should not exceed 90 V relative to the steel reference electrode.

Depending on the danger of the protected object, it is possible to connect from one to four lightning rods to one cathode converter, which should be located at a distance from each other, forming a square, as shown in FIG. 2. To determine the operating parameters of the cathode converter and the number of lightning rods for each specific object, a working protection project should be developed.

The claimed method for the joint protection of metal structures from lightning discharges and electrochemical corrosion has a triple technological and economic effect:

1. We get a protective lightning catcher with a potentially positive active ground loop. This will allow you to localize a negatively charged lightning discharge and give a forced direction from the protected object to an air terminal that has a positively charged ground electrode, which results in an effective controlled lightning protection system.

2. A potentially positive lightning rod and ground loop will actively divert a positively charged lightning charge from the protected object from the affected area of the object.

3. We carry out cathodic protection of the underground structure from electrochemical corrosion and reduce the economic costs of relocating underground utilities or structures due to corrosion damage.

It is known that on a global scale, the loss of metal from corrosion amounts to 30% of its production. In Russia, direct losses from corrosion make up 4% of the annual national income, which amounts to over 100 billion rubles. in the city, in America - 276 billion US dollars, in Germany - 63 billion US dollars, in England - 30 billion pounds, and in general, metal losses, according to experts from different countries, are 2-4% of the gross national product. These statistics testify to the global scale of the fight against corrosion. Losses are not limited to metal losses. Failure of expensive equipment, leakage of water, gas, oil, the creation of emergency situations and an increase in the risk of technological disasters, simple production, suspension of transport connections, ingress of corrosion products into the transported medium (oil, water, etc.) leads to a decrease in quality and environmental pollution Wednesday. According to the RF Security Council, oil losses as a result of accidents annually amount to 1.2% of production, i.e. not less than 3 million tons, while in 31% of cases of an accident due to corrosion damage.

As you know, in the Interstate standard GOST 9.602-2005 “Unified system of protection against corrosion and aging” four criteria of the danger of corrosion are considered, namely:

- corrosiveness of the medium in relation to the metal of the structure in terms of the specific electrical resistance of the soil and the average density of the cathode current;

- biocorrosive aggressiveness of the soil;

- the dangerous effect of stray direct current;

- the dangerous effect of stray alternating current of industrial frequency.

However, the criterion does not consider the differential aeration criterion on the bottom and walls of explosive storage tanks, located partly in a soil electrolyte, and partly on the surface. The occurrence of corrosive differential macropairs of aeration on the bottom of the steel tank is shown in FIG. 3.

Technologically, steel tanks 1 are partially located in the ground, and partially on the surface of the earth. On the bottoms of steel tanks in contact with the soil, corrosive macropairs of the edge effect are created as a result of various oxygen permeabilities. The edge of the bottom of the tank, the access of oxygen to which is free, becomes a cathode and does not corrode. At a distance of 0.25-0.5 meters from the bottom edge an anode zone is formed, to which oxygen access is difficult. This part of the bottom, usually 1-2 meters, depending on the diameter of the bottom, is subject to the greatest corrosion. In the center of the bottom, where the access of oxygen and moisture is most difficult, there will be the least favorable conditions for corrosion.

The value of soil resistivity in the area under the bottom of the tank 2 and in the soil layer at the site of the tank’s exit from the earth 3 is different, since the soil layer contains residues of rotting plants, active atmospheric precipitation, and various products from the operation of the tank. Considering oxygen aeration with obtaining different values of the electrochemical potential, the heterogeneity of the soil electrolyte relative to the value of the soil resistivity in individual underground sections of the steel tank location, the difference in stationary potentials of these sections of the structure can reach about ΔU = 0.25 volts. The speed of the corrosion process in this macropar is quite high, which leads to the failure of the tank and a reduction in design life. To protect such structures as tanks and reservoirs that are in the ground or bunded with soil from electrochemical corrosion, it is necessary to apply 100% cathodic polarization, and the application of the method of joint protection against lightning discharges and electrochemical corrosion will additionally ensure the safety of the structures under consideration from lightning discharges.

Thus, the hazard criterion for differential aeration and the difference in the soil resistivity for underground tanks should be included in the list of hazard criteria regardless of the use of insulation coatings and provide for mandatory protection of steel tanks from electrochemical corrosion to ensure the safe operation of hazardous production facilities. The design of the insulation coating should be applied in accordance with the requirements for the types of insulation described in the Interstate Standard GOST 9.602-2005 “Unified System of Protection against Corrosion and Aging”.

The application of the claimed method will ensure safety from lightning strikes, from intense electrochemical corrosion and will effectively affect the reduction of operating costs. This is not considered as toughening the requirements of industrial safety, but ensuring the safety of facilities in connection with the growing needs of production and the use of new technologies contributes to the safety of both the environment and human lives.

The described method is illustrated by drawings.

In FIG. 1 shows a connection diagram of a plant for protection against lightning discharges and electrochemical corrosion.

In FIG. Figure 2 shows the layout of the installation for protection against lightning discharges and electrochemical corrosion to protect several structures.

In FIG. 3 shows an image of the occurrence of corrosive macropairs of differential aeration and the difference in the values of soil resistivity on the bottom of the walls of a steel tank for storing liquefied gas.

Claims (1)

A method of protecting metal objects from electrochemical corrosion and lightning discharges, including the use of a cathodic protection system from electrochemical corrosion containing a direct current source and carbon graphite anode grounding, with a lightning protection system containing a rod lightning rod and a down conductor, by means of a contact device and a steel reference electrode, while carbon graphite anode grounding of the cathodic protection system is used as a grounding circuit of lightning protection, the operating modes are set you are the “thunder-free mode” and “thunderstorm mode”, and the cathodic polarization of metal objects is provided in a continuous mode, and the lightning removal mode is connected to the cathodic protection system during the period of danger of lightning discharges, while providing the discharge of lightning discharges from the protected object by pointing at the lightning protection system positive electrochemical potential, the value of which does not exceed 90 V relative to the steel reference electrode.

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