RU136805U1 - MULTILAYER POLYMER PRODUCT ANODE GROUNDING ELECTRODE - Google Patents

Abstract

1. An anode grounding electrode containing a current-setting polymer sheath, a current lead and an additional layer — a coke-backed sheath with a carbon content of at least 97 wt.% In it. 2. The electrode according to claim 1, characterized in that it is made with an outer diameter of the conductive polymer of 12.1-13.3 mm in size, comprising 0.45-0.55 of the total diameter of the electrode product. The electrode according to claim 1, characterized in that the typical resistivity of the coke shell is 4.0 · 10 Ohm · m. 4. The electrode according to claim 1, characterized in that the specific amount of coke backfill in the shell is at least 1.1 kg / mp 5. The electrode according to claim 1, characterized in that the current lead is made with an effective cross section of a copper conductor of at least 13.2 mm. The electrode according to claim 1, characterized in that the specific resistance of the copper conductor is not more than 1.5 · 10 Ohm · m.

Description

The field of technology.

The utility model relates to products used in the electrochemical protection of metal objects and is intended, in particular, for the cathodic protection of underground structures. The scope includes any objects of industrial, domestic, individual use.

The level of technology.

The development of modern polymer chemistry has allowed the creation of conductive polymers with special properties that allow their use in a wide variety of industries.

This device is designed to work in difficult climatic conditions when installing current-conducting circuits of anode grounding of corrosion protection installations - cathodic protection of metal and reinforced concrete structures. Polymer-containing electrodes are an important element in cathodic protection devices when underground structures come in contact with river water, soil, salt water, and also in contact with other electrolytic media, and is used in grounding devices for thunderstorm protection and protection against high voltages and static electricity.

In the prior art, combined multilayer products of several layers of an elastomer with metal are known — an extended elastomeric electrode, anode grounding and a deep anode ground electrode made in the form of a flexible conductive rod coated with one or more conductive elastomeric sheaths and / or combinations of elastomeric sheaths with carbon graphite fibers according to the patent RF 2225420 published. 2004. The disadvantages are that the technology for the manufacture of electrodes on a continuous vulcanization production line in a microwave field and an air heat vulcanizer (LVPR-300 line) is very complex and multi-stage and, like any multi-stage process, has low reliability.

Known multilayer polymer product elastomeric electrode according to the patent of Russian Federation 2291226, containing a shell of elastomer and made in the form of a multilayer sleeve, in which alternating layers of elastomeric material and layers of the current lead.

One of the closest to the claimed technical solution is an electrically conductive elastomeric composition for grounding elastomeric electrodes according to the patent of the Russian Federation 2225420, published. 2004, which describes a long grounding elastomeric electrode and anode grounding, which can increase the durability of elastomeric electrodes in comparison with other analogues. The disadvantage is the complexity and multi-stage technology for the manufacture of electrodes.

A known system with an anode element for cathodic protection against corrosion of underground structures, which is also a close analogue to the claimed utility model, disclosed in RU 2111283 publ. 1998. The system contains a current-collecting polymer shell and a current lead, which is equipped with an additional casing layer with a coke backfill (carbon rich material).

The disadvantage of the described "system" is that it does not solve the issue of improving the quality of the electrode itself, the issue of increasing its life, which inevitably leads to low reliability. This disadvantage is eliminated by the declared decision.

In addition, when using a new material for filling coke with a special content of non-carbon as an element of the electrode, as is known from the prior art, but bound carbon (as described in the formula of the claimed utility model), other basic performance characteristics of the elastomeric electrode, such as constant current propagation α [1 / m]; characteristic resistance Z [Ohm]; nominal specific density of the anode current J [mA / m]; anode dissolution rate q [kg / A * year].

In the claimed solution, a new backfill was used with a characteristic according to such a parameter as the content of bound carbon, that is, along the ashless part of coke.

The technical result.

The technical result of the claimed utility model is to increase by up to 50% the service life of such an electrode due to the implementation of such a shell that has not been previously applied, namely, with coke filling with a content of bound carbon of at least 97 wt%. It should be noted that such an amount of bound carbon in the backfilled shell, in addition to increasing reliability, improves other operating characteristics by 5-10% on average.

The technical result is achieved by the following set of essential features of the utility model, namely, that the anode grounding electrode contains a current-setting polymer shell, a current lead, and an additional layer — a shell with coke filling with a content of bound carbon of at least 97 wt%.

Additionally, the electrode can be made with an outer diameter of the conductive polymer measuring 12.1-13.3 mm, comprising 0.45-0.55 of the total diameter of the electrode,

- a typical resistivity of the coke shell may be 4.0 × 10-3 Ohm · m,

- the specific amount of coke backfill in the shell, not less than 1.1 kg / mp

- current lead can be made with an effective cross section of a copper conductor, not less than 13.2 mm ² ,

- the specific resistance of the copper conductor can be no more than 1.5 × 10 ^-3 Ohm · m.

The essence of the utility model.

Providing the device with an additional layer — a coke-coated shell with a carbon content of at least 97 wt% in it, provides the claimed technical result that not only improves performance by 5–10% on average, including distributed current output, but also increases by up to 50 % service life of such an electrode, i.e. increases the reliability of the utility model.

The declared device is used in cathodic protection systems:

- port and berthing facilities, offshore platforms and other hydraulic structures.

- underwater crossings of single-thread pipelines and their multi-thread systems;

- trunk, field and other pipelines and multi-pipe systems of pipelines in any soil, including rocky, arid, desert and permafrost;

- technological tanks for any purpose, including the inner surface;

- branched communications of compressor, gas distribution, oil pumping stations,

thermal power plants and industrial sites for other purposes.

The claimed device can operate in ambient temperature ranges from minus 60 ° C to plus 60 ° C.

Implementation of a utility model.

Example 1

The electrode contains a conductive polymer shell and a current lead, and consisting of layers of a conductive polymer with a metal current lead. The device is equipped with an additional layer - a shell with coke filling.

The content in the filling of bound carbon 99 wt.%.

When installing the supply cable, the device is equipped with insulation in the form of a sleeve with a layer of sealant and heat-shrinkable tube.

The outer diameter of the conductive polymer is 13.0 mm.

Typical specific resistance of coke shell is 4.0 × 10 ^-3 Ohm · m.

The specific amount of coke backfill in the shell, 1.1 kg / mp

The current lead is made with an effective cross section of a copper conductor of 13.2 mm ² .

The resistivity of the copper conductor is 1.5 × 10 ^-3 Ohm · m.

The installation was carried out from the bay from the side of the car.

A comparison of the characteristics was carried out in relation to the characteristics of the patent RU 2111283:

The tests showed an increase in reliability (i.e., correspondingly to the service life) in comparison with the indicated analogue by 47%, and the other above-mentioned performance characteristics improved by an average of 7%.

Example 2

An anode ground electrode was tested.

Electrode structure:

- current-carrying shell of a polymeric material,

- current lead,

- an additional layer is made in the form of a shell,

- coke is filled in the casing, the specific amount of coke filling in the casing is 1.2 kg / mp,

- the content of bound carbon 97.2 wt.%.

Moreover, the outer diameter of the conductive polymer is 12.9 mm.

The typical resistivity of the coke shell was 4.0 × 10 ^-3 Ohm · m,

- the current lead has an effective cross section of a copper conductor, 13.2 mm ² ,

- the specific resistance of the copper conductor is 1.45 × 10 ^-3 Ohm · m.

Laying was done using a pulling device.

A comparison of the characteristics was carried out in relation to the characteristics of the product according to the patent RU 2291226:

Tests showed that the increase in reliability (i.e., correspondingly to the service life) compared to the indicated analogue is 50%, and the other above-mentioned performance characteristics improved by an average of 10%.

Example 3

An anode ground electrode was tested.

Electrode structure:

- current-carrying shell of a polymeric material,

- current lead,

- an additional layer is made in the form of a shell,

- coke is filled in the casing, the specific amount of coke filling in the casing is 1.2 kg / mp,

- the content of bound carbon 97.2 wt.%.

Furthermore, the outer diameter of the conductive polymer is 12.1 mm.

The typical resistivity of the coke shell was 4.0 × 10-3 Ohm · m, and the current lead has an effective cross section of a copper conductor, 13.3 mm ² ,

The specific resistance of the copper conductor is 1,499 × 10-3 Ohm · m.

Laying was done using a pulling device.

Tests showed that the electrode life compared to the product according to patent RU 2111283 increased by 50%, and the other above-mentioned performance characteristics improved by an average of 8%,

Example 4

Structure of the fabricated electrode:

- current-carrying shell of a polymeric material,

- current lead,

- an additional layer is made in the form of a shell,

- coke with a content of bound carbon of 97.0 wt.% is filled in the casing, the specific amount of coke filling in the casing is 1.15 kg / mp,

Moreover, the outer diameter of the conductive polymer is 13.3 mm.

This diameter corresponded to 0.55 of the total diameter of the electrode,

The typical resistivity of the coke shell was 4.0 × 10 ^-3 Ohm · m.

The current lead has an effective cross section of a copper conductor, 13.2 mm ² .

And the resistivity of a copper conductor can be 1.5 × 10 ^-3 Ohm · m.

Laying was done from the drum using a cable layer.

A comparison of the characteristics was carried out in relation to the characteristics of the product according to the patent RU 2291226:

Tests showed that the increase in reliability (i.e., correspondingly to the service life) in comparison with the indicated analogue is 49%, and the other above-mentioned performance characteristics improved by an average of 10%.

Claims (6)

1. An anode grounding electrode containing a current-setting polymer sheath, a current lead and an additional layer — a coke-backed sheath with a carbon content of at least 97 wt.% In it. 2. The electrode according to claim 1, characterized in that it is made with an outer diameter of the conductive polymer with a size of 12.1-13.3 mm, comprising 0.45-0.55 of the total diameter of the electrode product. 3. The electrode according to claim 1, characterized in that the typical resistivity of the coke shell is 4.0 · 10 ^-3 Ohm · m 4. The electrode according to claim 1, characterized in that the specific amount of coke backfill in the shell is not less than 1.1 kg / mp 5. The electrode according to claim 1, characterized in that the current lead is made with an effective cross section of a copper conductor of at least 13.2 mm ² . 6. The electrode according to claim 1, characterized in that the resistivity of the copper conductor is not more than 1.5 · 10 ^-3 Ohm · m