RU2294584C1 - Anodic groundwire - Google Patents

Abstract

FIELD: technology for electrochemical protection of underground structures from corrosion and for transferring direct current in accordance to "wire - ground" system, and may be used during construction of anodic and working direct current ground connections.

SUBSTANCE: groundwire contains marginally soluble electrodes, serially mounted on each other, having a hollow with conic inlet in lower end, while upper end of each electrode enters a hollow of electrode positioned higher, and electrode with current inlet, positioned in arch section of electrode hollow, electrodes are made with thickening in hollow location zone, upper end of each electrode except the electrode located below electrode with current inlet is made with sharp edge, contacting the surface of conic inlet of hollow of electrode positioned higher, while upper end of electrode, positioned below electrode with current inlet, is provided with sharpened tip, contacting the surface of arch section of hollow of electrode with current inlet. Sharpened tip is fastened to end of reinforcing rod projecting from electrode. Tip and upper part of reinforcing rod of electrode, positioned below the electrode with current inlet, are made of corrosion-resistant steel. Electrodes are made with varying anodic resistance and cross-section, while in intervals of soil with high electric conductance, electrodes with high anodic resistance and/or cross-section are positioned.

EFFECT: increased reliability of groundwire.

7 cl, 2 dwg

Description

The invention relates to cathodic protection of underground structures against corrosion and direct-current electric power transmission through the wire-to-ground system, namely to direct-current grounding devices, and will find application in many industries.

Known deep anode ground electrode containing a garland of series connected to each other and connected to the main cable electrode blocks. The electrode blocks are placed in a metal casing filled with an activator and consist of two interconnected anodes rigidly connected to the casing (US Pat. RF No. 2138106, class H 01 R 4/66, C 23 F 13/00 dated 10/16/98) .

The disadvantage of the earthing switch is the design complexity, especially with a large number of electrode blocks, i.e. with a large length of the ground electrode, and low reliability due to the presence of electrical connections between the electrodes and the main cable, which require careful insulation with a hardening compound (resin, varnish or bitumen). The reliability of the ground electrode can also be reduced due to the fact that the metal casing and other metal elements for fastening the anodes during the operation of the ground electrode are quickly destroyed by the anode current flowing from the electrodes. In this case, the electrodes are shifted down and begin to be held only due to the trunk cable and the electrical wires connecting the electrodes, which can lead to damage.

The closest in technical essence to the proposed one is the anode earthing switch, which contains consecutively mounted electrodes on each other, having a cylindrical cavity with a conical inlet at the lower end, the upper end of each electrode being made conical, entering the cavity of the upstream electrode and forming a linear or point contact, and an electrode with a current lead located in the arched part of the electrode cavity. The upper end of each of the electrodes, except the upper, is made pointed to create a point contact between the tip of the end of the electrode and the surface of the cavity. In another embodiment, the electrode cavities are made with a sharp protrusion interacting with the lateral surface of the narrowed end of the electrode with the formation of a linear contact (US Pat. RF No. 1226561, class H 01 R 4/66 from 11.29.83).

In this ground electrode, the electrodes are in direct contact with each other under the influence of the weight of the upstream electrodes. Moreover, the contact is linear or point-like in nature, which prevents non-conducting soil particles from entering the contact, which not only increase the longitudinal resistance of the ground electrode, but also change the nature of the conductivity between the electrodes - instead of electronic, ionic conductivity appears, which is accompanied by anodic dissolution of the contact zone of one of the electrodes. The power cable leads only to the electrode with a current lead. Moreover, in the embodiment with pointed electrodes, the current lead is located in the upper part of the electrode cavity, which is essentially an inverted glass into which water cannot penetrate.

The disadvantage of this earthing switch is the lack of reliability due to the fact that during transportation the pointed ends of the electrodes are damaged, especially for electrodes made of such a brittle sparingly soluble metal as ferrosilide. This leads to deterioration of the contacts between the electrodes (a platform appears in the place of contact of the two electrodes, where soil particles can get). The low reliability of the variant with electrodes having sharp protrusions in the cavity is due to the impossibility of placing the current lead in a waterproof cavity, because the cable will prevent the contact of sharp protrusions with the conical side surface of the narrowed end of the electrode. The current lead in this embodiment is located at the upper end of the electrode and requires careful isolation and its preservation during transportation and operation, since when the insulation of the current lead is violated, water enters it and accelerates in time (due to the pressure-destroying insulation of the pressure of the metal dissolution products, the volume of which is larger than the volume of the dissolved metal) anode dissolution of the cable core.

The objective of the invention is to increase the reliability of the anode earthing switch.

The problem is solved in that in the anode earthing switch, which contains soluble electrodes in series with each other and having a cylindrical cavity with a conical entrance at the lower end, the upper end of each electrode entering the cavity of the upstream electrode and forming a linear or point contact with the cavity surface, the electrode with a current lead located in the arched part of the electrode cavity, and a current-carrying wire connected to the electrode through a current lead, according to the invention, the electrodes are made with a thickening in the cavity location zone, the upper end of each of the electrodes, except for the electrode located below the electrode with the current lead, is made with a sharp edge in contact with the surface of the conical inlet of the cavity of the upstream electrode, and the upper end of the electrode located below the electrode with the current lead is equipped with a pointed tip in contact with the surface of the arch portion of the electrode cavity with a current lead.

The electrodes may be provided with a central reinforcing steel rod, and the pointed tip of the electrode located below the electrode with the current lead is attached to the end of the reinforcing rod protruding from the electrode.

In addition, the current lead can be made in the form of a bare core of a lead wire immersed in a low-melting metal, such as lead, in a molten state, and is located in the arched part of the electrode cavity. Moreover, in the electrode with a current lead, the lower end of the reinforcing rod can be provided with lateral protrusions, for example, in the form of a thread and enters the cavity of the electrode.

The upper part of the reinforcing rod of the electrode located below the electrode with the current lead can be made of corrosion-resistant steel and welded to the main part of the reinforcing rod.

The pointed tip of the electrode located below the electrode with the current lead can also be made of corrosion-resistant metal or provided with a corrosion-resistant conductive coating.

The electrodes can be made with different cross-sectional area and / or materials with different anode resistance, and in the soil intervals with high electrical conductivity are placed electrodes with higher, and in the intervals with low electrical conductivity - electrodes with lower values of the cross-sectional area and / or anode resistance.

In the proposed ground electrode, the upper ends of the electrodes do not have a conical narrowing, which eliminates the possibility of damage to the contacting points. If the sharp edges of the upper ends of the electrodes during chipping are chipped, then point or linear contacting will occur along the undamaged parts of the edges, i.e. possible chipped edges do not affect the reliability of the contact of the two electrodes. The supply of the electrode located under the electrode with the current lead, a pointed tip allows you to contact these electrodes with the formation necessary for the passage of the power cable gap between these electrodes. This allows you to place the current lead in the cavity of the electrode, which is waterproof. The implementation of the upper part of the reinforcing rod and the pointed tip of the electrode located under the current lead from corrosion-resistant steel eliminates the possibility of atmospheric corrosion of these elements in a gas-filled cavity, where the gas has almost one hundred percent humidity.

The implementation of the electrodes with different cross-sectional areas and / or materials with different anode resistance, depending on the electrical conductivity of the surrounding soil electrodes, eliminates the accelerated destruction of the electrodes in highly conductive soil intervals. All this increases the reliability of the grounding.

The drawing shows a longitudinal section of the anode ground electrode (Fig. 1) and view A of the electrode tip located under the current lead (Fig. 2).

The earthing switch consists of the main electrodes 1 (Fig. 1), the number of which depends on the design length of the earthing switch (only one of such electrodes is shown in the drawing), an electrode 2 with a current lead, and an electrode 3 with a pointed tip 4 (Fig. 2) located under electrode 2 with a current lead. All electrodes have thickened lower ends in which cylindrical cavities with a conical inlet are made. The electrodes along the entire length or at the ends are provided with a carbon steel reinforcing rod 5. The upper part 6 of the reinforcing rod of the electrode 3 with a pointed tip and the tip 4 are made of stainless steel. The tip 4 is screwed onto the end of the reinforcing rod protruding from the electrode, and in order to prevent moisture (condensate forming in the gas cavity of the electrode 2 with the current lead) from penetrating the reinforcing rod, a flexible elastic gasket 7 and a corrosion-resistant washer are placed in series between the tip and the end of the electrode 3 8 (see figure 2).

The current lead is placed in the arched part of the electrode cavity 2, into which the lower end of the reinforcing rod 5 extends. Lead filling 10 is electrically connected to the electrode body in the current lead 10. To improve the mechanical fixation of the current lead elements, the end of the reinforcing rod is provided with lateral protrusions in the form of a conventional thread , and the end of the wire core is bent or flattened.

The earthing switch is lowered into a vertical well (pit) 11. The annular space between the earthing switch and the wall of the well is filled with an electrically conductive substrate 12 (water, clay, earth pulp or coke breeze). The upper part of the well, above the head of the ground electrode system, is filled with coarse-porous granular material 13, for example, gravel, to facilitate the release of gas released during operation of the electrode system.

In soils with a sharp layer-by-layer heterogeneity in electrical conductivity, opposite to soil layers with high electrical conductivity, it is advisable to install electrodes with a higher anode resistance, or with a large cross section, or with large resistance and cross section at the same time. In the General case, the cross section S _i and the anode resistance, determined by the rate of anode dissolution of the anode material q _i (the lower the rate of anode dissolution, the higher the anode resistance) of the electrodes in the soil layers with electrical conductivity χ _{i are} calculated by the formula:

where S _i is the cross-sectional area of the electrode in the i-th soil layer, m ² ; q _i is the rate of anodic dissolution of the electrode material in the i-th layer, kg / (A · year); χ _i - electrical conductivity of the i-th soil layer, (Ohm · m) ^-1 ; S, q, χ are the average values of the corresponding parameters calculated for a homogeneous soil.

If the cross sections and the rate of anodic dissolution of the electrodes in soil layers with different electrical conductivity satisfy the above dependence, then the relative anodic dissolution (in% of the initial mass) of all electrodes will be approximately the same, which increases the service life of the ground electrode.

Anode grounding works as follows.

A constant electric current from a source (not shown in the drawing) through a current-carrying wire 9 is supplied to an electrode 2 through a current lead 10 and to an electrode 3 through a tip 4. A part of the current flows from electrodes 2 and 3 into the ground through an electrically conductive substrate 12, and the remaining part of the current through the electrical contact between the electrodes 1 and 3 flows into the electrode 1 and flows from it into the ground. In the process of draining direct current from sparingly soluble electrodes 1-3, an electrochemical decomposition of water occurs on their working surface, accompanied by the release of molecular oxygen. The gas released from the surface of the electrodes, rising up, fills all the cavities of the electrodes, displacing water from them. This eliminates the leakage of current from the points of contact between the electrodes and the junction of the wire with the current lead. Therefore, the anodic dissolution of the metal elements of the current lead and electrodes in the area of their contact under the action of the current flowing from them does not occur. These elements can only be corroded in a humid gas atmosphere. To exclude this corrosion, it is sufficient to carry out current lead elements from corrosion-resistant steel (for example, 08X18H10T) or from non-ferrous metals resistant to atmospheric corrosion (lead, tin, copper and its alloys, etc.). You can also perform some of these elements (for example, tip 4) of carbon steel coated with a corrosion-resistant conductive coating.

The proposed earthing switch has passed long-term (more than 5 years) tests in real operating conditions at OAO TATNEFT with electrochemical protection of underground structures and has shown high reliability and availability.

Claims (7)

1. An anode earthing switch, containing poorly soluble electrodes sequentially mounted on top of each other, having a cylindrical cavity with a conical inlet at the lower end, the upper end of each electrode entering the cavity of the upstream electrode and forming a linear or point contact with the surface of the cavity, an electrode with a current lead placed in the arched part of the electrode cavity, and a current-carrying wire connected to the electrode through a current lead, characterized in that the electrodes are made with a thickening in the area of the floor In addition to the electrode located below the electrode with the current lead, the top end of each electrode is made with a sharp edge in contact with the surface of the conical inlet of the cavity of the upstream electrode, and the upper end of the electrode located below the electrode with the current lead is equipped with a pointed tip in contact with the surface of the arch parts of the electrode cavity with a current lead. 2. The anode ground electrode according to claim 1, characterized in that the pointed tip of the electrode located below the electrode with the current lead is made of corrosion-resistant metal or is provided with a corrosion-resistant conductive coating. 3. The anode ground electrode according to claim 1, characterized in that the current lead is made in the form of a bare core of a current-carrying wire immersed in a low-melting metal, for example, lead, in a molten state, and is located in the arched part of the electrode cavity. 4. The anode ground electrode according to claim 1, characterized in that the electrodes are provided with a central reinforcing steel rod, and the pointed tip of the electrode located below the electrode with the current lead is attached to the end of the reinforcing rod protruding from the electrode. 5. The anode ground electrode according to claim 4, characterized in that in the electrode with a current lead the lower end of the reinforcing rod is provided with lateral protrusions, for example, in the form of a thread and enters the electrode cavity. 6. The anode ground electrode according to claim 4, characterized in that the upper part of the reinforcing rod of the electrode located below the electrode with the current lead is made of stainless steel and welded to the main part of the reinforcing rod. 7. The anode ground electrode according to claim 1, characterized in that the electrodes are made with different cross-sectional area and / or from materials with different anode resistance, moreover, in the intervals of the soil with high electrical conductivity, electrodes with higher and in the intervals with low electrical conductivity are placed electrodes with lower values of cross-sectional area and / or anode resistance.

Images