RU69522U1 - PROTECTOR FOR PROTECTION AGAINST CORROSION OF GAS-OIL PRODUCTS - Google Patents

Abstract

The utility model relates to construction, namely, to means for protection against underground corrosion caused by groundwater, various metal structures, for example, steel pipelines, fuel tanks, etc. The tread for corrosion protection of oil and gas pipelines contains a magnesium anode 1, a contact core 2 connected by an insulated wire 3 to the protected structure. The anode 1 is placed in a bag 4, filled with a powder activator 5, while the insulated wire 3 connecting the contact core 2 of the anode 1 with the protected structure, passes the neck of the bag 4. The junction of the insulated wire 3 with the contact core 2 of the anode 1 is isolated from the external environment by a dielectric 6 , which can be used petroleum bitumen, bitumen-rubber mastic, epoxy resin with a hardener. Using the claimed solution provides reliable and long-term autonomous electrochemical protection of oil and gas pipelines from underground corrosion. 1 ill.

Description

The utility model relates to construction, namely, to means for protection against underground corrosion caused by groundwater, various metal structures, for example, steel pipelines, fuel tanks, etc.

To assess the novelty and industrial applicability of the claimed solution, we consider a number of well-known technical means of a similar purpose.

Known tread for corrosion protection of metal structures, for example, welded joints inside the pipeline, see RF patent No. 2194914, F16L 58/00. The working element of the tread is made in the form of a tire reinforced with reinforcement with holes along its length. The tire is made with the possibility of bending, and the reinforcement holes are aligned with the holes of the tire. The diameter of the reinforcement holes is selected in the range of 0.5-1.0 diameter of the tire holes. The location of the holes provides fastening of the tread inside the pipeline and the maximum use of the mass of the working element.

Known tread for corrosion protection of metal structures, in particular for corrosion protection of vehicles, see RF patent No. 20159578, C23F 13/00. The tread is mounted on a metal structure in a perforated casing enclosing it with a gap, attached to a metal structure, and is equipped with an activator made in the form of at least one solid body from textolite and placed in the said gap with the possibility of movement, while the casing is made vibrating, and in activator introduced abrasive powder in an amount of 25.0-98.0 wt.% activator. In addition, an air supply chamber installed on the lower side of the perforated part of the casing, a gas distribution grill located on the perforated part of the casing and connecting the latter to the air supply chamber, and an air pulsator with a follower connected by a pipeline to the air supply chamber can be introduced into the device. In addition, the device can be performed with a corrosion control sensor of a metal structure mounted on the latter and electrically connected to the tracking device. In this case, the vibration source can be made in the form of a sound oscillation generator connected

by means of elastic elements with a casing and electrically - with a corrosion control sensor of a metal structure and with a tracking device.

Known aluminum tread for corrosion protection of steel structures of marine hydraulic structures, consisting of casting an aluminum tread alloy and a steel core connected to the protected structure, which is characterized in that the core is made in the form of a sphere with positive buoyancy and connected to the protected structure with a buoyer, see USSR copyright certificate No. 1675837, C23F 13/00.

Known tread for corrosion protection of oil and gas pipelines, consisting of an anode made in the form of a metal casting and a contact core connected to a protected structure, characterized in that the anode is made in the form of an alloy casting, the basis of which is magnesium, and placed in a bag filled with powder activator, while an insulated wire is passed through the neck of the bag connecting the contact core of the anode with the protected structure, see RF patent No. 35576, C23F 13/00. In this protector, the anode is made of magnesium alloy with the following combination of components,%: aluminum 0.1-8.0, zinc 0.1-7.0, manganese 0.001-1.0, impurities - not more than 2.0, magnesium - rest. As an activator can be used a dry powder mixture consisting of 35-65% bentonite clay, 10-40% gypsum and 10-40% sodium sulfate. The activator bag is made of dense cotton coarse calico. A zinc layer is applied to the surface of the contact core.

According to the greatest number of similar features, this technical solution is selected as a prototype of the claimed utility model.

The disadvantages of the prototype are the low reliability of the contact point of the insulated wire connecting the tread anode with the protected structure, and the contact core of the anode, which reduces the efficiency when protecting various long underground pipelines from underground corrosion.

The purpose of the claimed utility model is to eliminate the above disadvantages of the prototype and create a structurally simple and effective tread for reliable and long-term autonomous electrochemical protection of oil and gas pipelines from underground corrosion.

The essence of the claimed utility model is expressed in the following set of essential features, sufficient to achieve the above technical result.

According to the claimed utility model, the tread for corrosion protection of oil and gas pipelines, consisting of an anode made in the form of a metal casting of a magnesium alloy and a contact core placed in a bag filled with a powder activator, through the neck of which an insulated wire is passed connecting the contact core of the anode with the protected structure, is characterized the fact that the junction of the insulated wire with the contact core of the anode is isolated from the external environment by a dielectric.

This is the totality of essential features that provides a technical result in all cases to which the requested amount of legal protection applies.

In addition, the claimed decision has optional features characterizing its particular cases, namely:

- petroleum bitumen can be used as a dielectric;

- bitumen-rubber mastic can be used as a dielectric;

- an epoxy resin with a hardener can be used as a dielectric.

The applicant has not identified sources containing information about technical solutions, the essential features of which are identical to those of the claimed utility model, which allows us to conclude that it meets the criterion of "novelty."

Due to the implementation of the distinguishing features of the claimed utility model, a significant improvement in the operational characteristics of the tread and an increase in the period of its autonomous operation on long underground structures are provided.

The essence of the utility model is illustrated by the drawing, which shows a cross section along the claimed tread.

The tread for corrosion protection of oil and gas pipelines contains a magnesium anode 1, a contact core 2 connected by an insulated wire 3 with a protected structure (not shown in the drawing). The anode 1 is placed in a bag 4 filled with a powder activator 5, while through the neck

water 3, connecting the contact core 2 of the anode 1 with the protected structure, passed through the neck of the bag 4. Bag 4 for the activator is made of dense cotton coarse calico. A zinc layer is applied to the surface of the contact core. The tread is packed in a woven bag 5 made of polypropylene and polyethylene. The junction of the insulated wire 3 with the contact core 2 of the anode 1 is isolated from the external environment by a dielectric 6, which can be used as oil bitumen, bitumen-rubber mastic, epoxy resin with a hardener

The device operates as follows.

The principle of operation of the claimed tread is to create a protective potential during the flow of current in a galvanic pair "metal pipe body - tread anode". The stationary potential of the anode 1 of the tread is more negative than the metal potential of the pipeline body. When the circuit “metal pipe body - insulated wire 3 - contact core 2 - anode 1 of the tread” is closed, the latter becomes an anode, and the pipe body becomes a cathode. The current flowing from the anode 1 of the tread passes through an electrolyte (drainage water), enters the pipeline body and ceases the action of corrosion processes on its surface, and hence the corrosion destruction of the pipeline body. The activator 5 enhances the potential of the anode 1 of the tread, increasing the efficiency of the tread as a whole. Coating the surface of the contact core 2 with zinc ensures its full contact with the anode. Insulating the junction of the insulated wire 3 with the contact core 2 of the anode 1 from the external environment by means of dielectrics increases the reliability and durability of the contact of the insulated wire 3 with the contact core 2 of the anode 1.

The possibility of industrial application of the claimed technical solution is not in doubt, since it can be implemented using well-known components and technical means, which determines, according to the applicant, its compliance with the criterion of "industrial applicability".

Using the claimed solution provides reliable and long-term autonomous electrochemical protection of oil and gas pipelines from underground corrosion.

Claims (4)

1. The tread for corrosion protection of oil and gas pipelines, consisting of an anode made in the form of a metal casting of a magnesium alloy and a contact core placed in a bag filled with a powder activator, through the neck of which an insulated wire is connected connecting the contact core of the anode with the protected structure, characterized in that the junction of the insulated wire with the contact core of the anode is isolated from the external environment by a dielectric. 2. The tread according to claim 1, characterized in that oil bitumen is used as the dielectric. 3. The tread according to claim 1, characterized in that bitumen-rubber mastic is used as the dielectric. 4. The tread according to claim 1, characterized in that an epoxy resin with a hardener is used as the dielectric.