RU128019U1 - DEPTH ANODE EARTH - Google Patents

Abstract

1. A deep anode earthing switch, comprising a garland of units of individual earthing switches connected in series to each other, each of which includes a working electrode placed in a supporting metal structure with an attachment cable, and means for connecting units of single earthing switches to a garland, characterized in that each unit of unit earthing switches includes a working electrode placed in a supporting metal structure made in the form of a frame frame with the possibility of open contact of soil and soil electrolyte with at least one insert made of flexible electrically conductive material is installed between the electrode and the frame frame. The deep anode earthing conductor according to claim 1, characterized in that the means for connecting the units of single earthing cones into a garland are made in the form of paired brackets with coaxial holes located in the upper and lower parts of the frame frame, and fixing fingers made with the possibility of simultaneous placement in the holes of paired the brackets of adjacent blocks, while the upper brackets of the blocks include a pair of additional coaxial holes located between the main holes and the upper edge of the frame frame. 3. The deep anode ground electrode system according to claim 1, characterized in that it includes a perforated gas outlet pipe, while the frame frames include elements for its fastening. The deep anode earthing conductor according to claim 1, characterized in that the frame frames include elements for attaching connection cables extending from downstream unit earthing units. Depth Anode Earthing

Description

The utility model relates to the field of electrochemical protection of underground metal structures from corrosion and can be used in the construction of deep anode and working grounds.

Known anode earthing switch, containing poorly soluble electrodes sequentially mounted on top of each other, having a cylindrical cavity with a conical entrance in 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 arch parts of the cavity of the electrode, and a lead wire connected to the electrode through a current lead [Description of the invention to the patent of the Russian Federation No. 2294584 dated 02.06.2005, IPC H01R 4/66, publ. 02/27/2007].

The disadvantages of this technical solution are the difficulty of joining the electrodes with each other, the likelihood of soil getting into the contact zone of the electrodes, which can lead to a lack of contact between the electrodes or an increase in transient resistance between them, as well as the absence of redundant current leads, which makes the protection of structures not reliable enough.

Known anode ground electrode comprising an upper electrode with a current lead and a conductive wire connected to the electrode through a current lead, poorly soluble electrodes mounted on top of each other, having at the lower end of the extensions with a cylindrical cavity and a conical butt surface, the upper end of each electrode entering the cavity of the upstream electrode made with the possibility of interaction with the conical butt surface with the formation of a linear or point contact, and the lower electrode equipped with tion of current leads with an additional conductive wire. [Description of the invention to the patent of the Russian Federation No. 2396373 dated 05/12/2009, IPC C23F 13/06, H01R 4/66, publ. 08/10/2010]. The earthing switch is distinguished by its simplicity of design and the ability to provide control over its condition during use, by connecting conductive wires to the ground electrode from above and below.

The disadvantages of this technical solution include all the disadvantages of the previous product, with the exception of the lack of redundant current leads. The presence of only one backup current lead increases the reliability of the ground electrode, however, the electrode connections to each other are still not reliable enough.

The closest to the set of essential features the claimed technical solution is an anode ground electrode containing a garland of interconnected earthing blocks, each of which includes a working electrode located in a hollow housing filled with an activator, and an accessory cable, as well as a gas outlet pipe installed on the housing with the possibility of outputting it together with the cable to the surface and means for connecting the earthing units to a garland [Description of the utility model to the patent of the Russian Federation No. 44422 of 08.12.2004, IPC ⁷ C23F 13/00, H01R 4/66, publ. 03/10/2005]. The earthing switch is characterized by low transient resistance, improved transportability and installation.

The disadvantage of this technical solution is the relatively large weight of the blocks due to the presence of heavy metal structures and coke-mineral backfill, sufficient design complexity, the complexity of manufacturing and the relative complexity of mounting the earthing lamp due to the outer diameter of the ground electrode and its increased weight.

The problem the utility model is aimed at and the technical result achieved consists in creating a lightweight design of a deep anode ground electrode system, simplifying it, increasing reliability during operation, improving manufacturability, redundant current leads, reducing the size and making it possible to carry out loading and unloading operations manually or with minimal attraction of means of mechanization.

To solve the problem and achieve the claimed technical result in a deep anode earthing switch, containing a garland of units of individual earthing switches connected in series to each other, each of which includes a working electrode placed in the supporting metal structure with an attachment cable, and means for connecting units of single earthing switches to a garland, each unit of individual earthing switches includes a working electrode placed in a supporting metal structure made in the form of a frame frame with the possibility of NOSTA open contact soil and groundwater of the electrolyte to the working electrode surface, the electrode and between the rack set, at least one insert of flexible electrically conductive material. Besides:

- the means for connecting the units of single earthing switches into a garland are made in the form of pair brackets with coaxial holes located in the upper and lower parts of the frame frame, and fixing fingers made with the possibility of simultaneous placement in the holes of the pair of brackets of adjacent blocks, while the upper brackets of the blocks include a pair additional coaxial holes located between the main holes and the upper edge of the frame frame;

- the ground electrode includes a perforated gas outlet pipe, while the frame frames include elements for its fastening;

- frame frames include brackets for attaching connection cables extending from downstream unit earthing switches;

- the frame frame of the lower block of individual earthing is made pointed.

The utility model is illustrated in the drawing, where:

- figure 1 shows a General view of a single block of deep anode ground electrode;

- figure 2 shows a General view of a single block of deep anode ground electrode system, namely the lower block, the frame frame of which is made pointed;

- figure 3 - installation of the ground electrode in the well and its preparation for assembly in the garland using the fixing fingers;

- figure 4 shows the connection of neighboring units of individual earthing using fixing fingers - a garland of earthing is prepared for installation in the well.

The deep anode earthing switch contains a garland of unit 1 and 1 ′ earthing switches connected to each other in series, each of which includes a working electrode 2 with a connection cable 3 located in the supporting metal structure, and means for connecting unit 1 and 1 ′ unit earthing switches to a garland, this, each block 1 and 1 'of individual earthing switches includes a working electrode 2 located in the supporting metal structure, made in the form of a frame frame 4 with the possibility of open contact of soil and soil electrolyte with the working surface of the electrode 2, while between the electrode 2 and the frame frame 4 is installed at least one insert 5 of flexible electrically conductive material.

The means for connecting the units of individual grounding conductors into a garland according to one of the options are made in the form of paired brackets 6 and 7 with coaxial holes 8 located in the upper and lower parts of the frame frame 4, and fixing fingers (metal rods, bolts, etc.) 9 made with the possibility of simultaneous placement in the holes 8 of the pair of brackets 6 and 7 of neighboring blocks 1 (on the block 1 'there are only brackets 6), while the upper brackets 6 of blocks 1 and 1' include a pair of additional coaxial holes 10 located between the main openings 8 and the upper edge of the frame 4.

The anode earthing can include a perforated gas outlet pipe 11, while the frame frames 4 can include elements of its fastening 12, as a rule, these are metal brackets welded to the frame 4. Frame frames 4 may also include brackets of a similar design (not shown in the figures) for attaching connection cables 3 extending from downstream unit 1 of the earthing switch, starting from block 1 ', the lower frame frame 4 of which is made pointed in its lower part.

Let us analyze the essential features of a utility model.

The implementation of the blocks 1 and 1 'of individual grounding electrodes in the form of working electrodes 2, placed in the supporting metal structure - frame frame 4, with the possibility of open contact of the soil and lithium soil electrolyte with the working surface of the electrode 2, with inserts 5 of flexible electrically conductive material between the electrode 2 and frame frame 4, allowed to make the anode ground electrode as light as possible. Such a design has nothing "superfluous" in terms of the function performed. In addition, during loading, transportation, unloading and installation, it is possible to visually assess the condition of products, their completeness, to check the presence of the necessary contacts and the reliability of the fastenings of grounding elements.

Inserts 5 made of flexible electrically conductive material between the electrode 2 and the frame frame 4 are designed for accelerated dissolution of the metal structures of blocks 1 and 1 'during the operation of the ground electrode. Theoretically, the contact between the electrode 2 and the frame 4 will be even without these inserts 5, it is simply guaranteed with them.

Means for connecting the blocks of single grounding in a garland made in the following version.

This is the presence of paired brackets 6 and 7 with coaxial holes 8 located in the upper and lower parts of the frame frame 4, and fixing fingers (metal rods, bolts, etc.) 9, made with the possibility of simultaneous placement in the holes 8 of the paired brackets 6 and 7 adjacent blocks 1, and in block 1 'only in brackets 6, while the upper brackets 6 of blocks 1 and 1' include a pair of additional coaxial holes 10 to facilitate the installation of grounding in the well, and specifically for hanging using, for example, durable erased metal reaper 13 on prismatic supports 14 at the wellhead 15 of the first block 1 'of grounding conductors and a garland of similar unit blocks 1.

This embodiment of the means for connecting a plurality of blocks 1 and a block 1 'of single earthing switches into a garland provides simplicity, manufacturability and reliability of the structure. There is an opportunity for redundant current leads. Under the redundancy of the current leads of the entire grounding system is understood the presence of power cables - connection cables 3 for each unit block 1 (and 1 ') separately. In the technical solution for the patent of the Russian Federation No. 2294584, the cable is one and is attached only to the upper block, in the technical solution for the patent of the Russian Federation No. 2396373 - to the first and last, in the claimed solution - to each unit 1 (and 1 '). At the exit of the metal structure, the connection cable is protected from mechanical damage, for example, by a plastic tube 16.

When the ground electrode is operating on the surfaces of the electrodes 2, gas is released. If there is no exit, it accumulates and, being an effective insulator, reduces the working surface area of the electrode 2. The presence of a perforated gas outlet pipe 11 in the ground electrode structure, which is securely fixed to the frame frames 4 of the blocks 1 (and 1 ') using its fastening elements, the brackets 12 provides, in the case of its use, the unhindered exit of the gas formed during the work of grounding to the surface of the earth.

The frame frames 4 also include similar brackets (not shown in the figures) for attaching the connection cables 3 extending from the downstream unit 1 (and 1 ') of the individual earthing switches. Thus, it is possible to mount the garlands of neatly lay cable harnesses of connection cables 3, which will not impede the passage of coke and mineral backfill at the final stage of the earthing switch installation in the well 15. For the convenience of lowering the garland and preventing injury to the walls of the well, 15 frame frame 4 of the lower unit Г of unit earthing switch is made pointed.

Blocks 1 and 1 'of the deep anode earthing switch are assembled in the factory and come fully ready for installation.

The assembly and installation of the earths in the well 15 is carried out sequentially, starting from the lower block 1 ', having the longest connection cable 3 and ending with the upper block 1, having the shortest connection cable 3.

Block 1 'with a pointed end is installed first in the well. This can be done manually. On the edges of the wellhead 15 lay a pair of prismatic supports 14 for hanging the block. For example, a metal rod (or scrap) 13 is threaded into additional holes 10 and the block 1 'is lowered into the well 15. Using a lifting device (truck crane, rig winch, etc.), another block 1 is fed from the top to the slings. Cables 3 of both blocks 1 'and 1, if possible, should be on one side. The second block 1 is connected to the first block 1 '- they are fastened to each other with the help of fixing fingers (metal rods, fixing bolts, etc.) 9. In all cases, the fastening elements 9 provide a reliable, strong and durable connection. If necessary, fasten the exhaust pipe 11, attach the connection cables 3. Next, hang the garland from two blocks 1 'and 1, take out the rod (or crowbar) 13 and lower it into the well 15. At the moment when the upper part of the second block 1 reaches the mouth wells 15, descent is stopped. Those. when the upper (also regular) block 1 reaches the surface of the supports 14, a rod (or crowbar) 13 is also threaded through holes 10. A two-block garland is hung out and the third block 1 is mounted. And so on, until a grounding conductor of the required length is obtained. The connection cables 3 and the vent pipe 11 exit at the wellhead 15 or to the surface.

By installing the garland at the design depth in the well 15, free space is filled, for example, with local soil, clay-salt solution, coke-mineral activator (for example, according to RF patent No. 2161353), etc. After that, the arrangement of the wellhead 15 is made and the garland is connected to the cathodic protection station (not shown in Fig.).

When an electric current is applied to the working electrodes 2 of block 1 '(with a pointed end) and a plurality of blocks 1 forming a garland around the ground electrode, an electric field is created, which leads to electrochemical dissolution of the metal structures of blocks 1' and 1 and working electrodes 2.

As a result of using the utility model, a simple and lightweight design of a deep anode ground electrode system was created, which is characterized by increased reliability during operation, the manufacturability of its manufacturing has improved, backup current leads have appeared, the dimensions of the device have decreased, and it has been possible to carry out loading and unloading operations manually or with minimal involvement of mechanical means.

Claims (5)

1. A deep anode earthing switch, comprising a garland of units of individual earthing switches connected in series to each other, each of which includes a working electrode placed in a supporting metal structure with an attachment cable, and means for connecting units of single earthing switches to a garland, characterized in that each unit of unit earthing switches includes a working electrode placed in a supporting metal structure made in the form of a frame frame with the possibility of open contact of soil and soil electrolyte with the working surface of the electrode, while between the electrode and the frame frame is installed at least one insert of flexible electrically conductive material. 2. The deep anode earthing conductor according to claim 1, characterized in that the means for connecting the units of single earthing cones into a garland are made in the form of paired brackets with coaxial holes located in the upper and lower parts of the frame frame and fixing fingers made with the possibility of simultaneous placement in the holes of the pair of brackets of adjacent blocks, while the upper brackets of the blocks include a pair of additional coaxial holes located between the main holes and the upper edge of the frame frame. 3. The deep anode ground electrode system according to claim 1, characterized in that it includes a perforated gas outlet pipe, while the frame frames include elements for its fastening. 4. The deep anode ground electrode system according to claim 1, characterized in that the frame frames include elements for attaching connection cables extending from downstream unit earthing switches. 5. The deep anode ground electrode system according to claim 1, characterized in that the frame frame of the lower block of individual ground electrodes is made pointed.

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