RU85486U1 - ANODE GROUNDER - Google Patents

Abstract

1. Anode earthing switch, comprising a hollow molten metal case as an electrode and a lead-in cable with a tip secured inside the case by means of a mechanical attachment unit, insulated with the tip of the lead-in cable from the external environment, characterized in that the case is made of ductile iron in the case wall a through hole is made, the attachment unit being installed in this through hole, and the tip of the supply cable is fixed directly to the inner surface of the housing. ! 2. Anode ground electrode system according to claim 1, characterized in that the housing is made of ductile iron with spherical graphite. ! 3. Anode ground electrode system according to claim 1 or 2, characterized in that the housing is made in the form of a pipe. ! 4. The anode ground electrode according to claim 1 or 2, characterized in that the surface sections of the housing around the through hole, at least from the outside, are made flat, and the fastening unit is made in the form of a bolt-nut connection or in the form of a rivet connection. ! 5. Anode ground electrode system according to claim 1 or 2, characterized in that the mechanical attachment point with the tip of the supply cable is isolated from the external environment by a layer of epoxy compound and, if necessary, a heat-shrink sleeve.

Description

The proposed technical solution relates to the field of corrosion inhibition of metal objects in contact with a conductive medium, in particular, with open ground. The anode earthing switch is designed to be placed in the ground near a metal object to be protected from corrosion, so that when connecting the ground electrode and the object to different poles of the current source (cathode station), a potential difference is created at the boundary of the object and the soil, which neutralizes electromotive force (e.m. .s.) at this boundary, and preventing electrochemical corrosion. The performance and cost of its production depend on the design and on the choice of materials.

Known anode ground electrode according to patent RU 54949, C23F 13/00, 2006.07.27. It is made in the form of a continuous cast metal cylinder, from one end of which an embedded metal sleeve is hermetically mounted along the axis. Along the axis of the sleeve is a recess of stepped cylindrical shape. In the narrow part of the recess (i.e. in the seat), the bare end of the cable is fixed with a wedge, and the wide part of the recess is filled with a heat-shrinkable resin, which forms an electrical and waterproofing plug. A bushing with a wedge and cable end forms a contact assembly and a mounting assembly in a broad sense. The disadvantage of this ground electrode system is the fragile material of the case, which does not allow the cable to be fixed with a wedge in a recess made directly in the case. The use of embedded bushings made of durable alloy complicates and increases the cost of production of an earthing switch.

Known anode ground electrode according to patent RU 61291, C23F 13/00, 2007.02.27. This earthing switch also has a cast housing with axial symmetry. The contact node is also formed by a plug-in sleeve with a recess (seat), a wedge and the end of the cable. The sleeve is partially hermetically mounted in the bottom of the recess, made in the end of the cast housing. After fixing the cable, the recess made in the end of the housing is filled with a chemically resistant sealant. The disadvantage of this earthing switch is also the fragile material of the case, which does not allow fastening directly to the case. The use of embedded bushings complicates and increases the cost of the production of an earthing switch.

Known anode earthing device ELZHK, version 2, manufactured by the Yugsnabservice Group of Companies (Russian Federation, Rostov Region, Novocherkassk, 106 Yermak Ave., Internet address http: //www.uss.rn/elektrohim, 2009.02.03). Its body is cast from an iron-silicon alloy and is equipped with a threaded steel sleeve and a mounting pin. This design allows the fastening of the tip in the form of the bare end of the cable. The disadvantage of the design of the contact node is the need to secure the sleeve in the molded case, due to the fragility of the material of the case, which complicates and increases the cost of the production of an earthing switch.

Known anode ground electrode system "Mendelevets MM" manufactured by CJSC PPMTS Permsnabsbyt (Russia, Perm, ul. Karbysheva 32, Internet address http://www.pss.ru, 2009.02.03). This earthing switch has a molded case made of iron-silicon alloy. The contact node is formed by a plug-in sleeve in which the bare end of the cable is fixed. The disadvantages are the fragility of the housing material and the design of the contact node (attachment node), which requires fixing (fusion) of the sleeve in a molded case, which complicates and increases the cost of production of an earthing switch.

The closest analogue of the proposed technical solution is the anode ground electrode, presented in the regulatory building document “Typical building structures, products and units. Units and details of the electrochemical protection of underground engineering networks from corrosion ”, series 5.905-17.07, issue 1, part 1. Working drawings developed by OAO SPKB“ Gazproekt-BTC ”(15 Uralskaya St., Krasnodar, Russia) and put into operation 02.16.2007, pp. 15-16. In the design of this ground electrode system, a standard pipe with a bell of ЧН Р150 Х 3000 Б or ЧН Р150 Х 6000 Б made of cast iron is used as a body. In the cavity of the body, namely inside the socket, a round flat metal plate (an intermediate part between the body and the tip of the supply cable) is attached to the pipe walls by a welded joint. A through hole for the bolt is made in the center of the plate. The contact node in the broad sense is formed by a plate, a flat terminal-terminal (having a through hole or cut-out) of the cable and a mechanical fastening unit (in this case, a bolt with a nut, with which the terminal is pressed against the plate - an intermediate part; the word "mechanical" is used to distinguish from fastening by welding, soldering, fusion, etc.). The weld along the perimeter of the plate also enters the contact node, as it also requires environmental protection. The contact node is isolated from the environment by filling with oil bitumen. This anode earthing switch has interconnected disadvantages: the fragility of the housing material, the limited resource of the earthing switch and the complexity of the production of the earthing switch, which negatively affects the cost of the earthing switch.

The task to which the proposed utility model is directed is the creation of an anode ground electrode having a more advanced (simple and technological) design, which will reduce the cost of its production, as well as having increased strength, which will increase its reliability and service life (lifetime).

This problem is solved in that the anode ground electrode contains a hollow cast metal housing as an electrode made of high-strength cast iron, and a lead-in cable with a tip fixed inside the housing directly on the inner surface of the housing using a mechanical fastener mounted in a through hole made in the wall case, while the attachment point with the tip is isolated from the external environment. The term "ductile iron" is used in the meaning adopted in metallurgy.

The implementation of the body of the anode ground electrode of high-strength cast iron is an essential feature that distinguishes the proposed technical solution from the closest analogue.

The presence of a through hole made in the wall of the housing is an essential feature that distinguishes the proposed technical solution from the closest analogue.

The fastening of the tip of the supply cable directly on the inner surface of the housing is an essential feature that distinguishes the proposed technical solution from the closest analogue.

Installation (location) of the mount in a through hole made in the wall of the housing is an essential feature that distinguishes the proposed technical solution from the closest analogue.

The implementation of the body of the anode earthing switch of high-strength cast iron with spherical graphite is an essential feature characterizing a particular case of the proposed technical solution and distinguishing this particular case from the closest analogue.

The implementation of the housing of the anode ground electrode in the form of a pipe is an essential feature characterizing a particular case of the proposed technical solution.

The execution of sections of the surface of the housing around the through hole, at least from the outside, is flat, in conjunction with the execution of the mechanical fastener in the form of a bolt-nut connection or in the form of a rivet connection, is an essential feature characterizing a particular case of the proposed technical solution and distinguishing this particular case from the closest analogue.

The isolation of the mechanical attachment point with the tip of the supply cable from the external environment with an epoxy compound layer and, if necessary, a heat shrink sleeve is an essential feature characterizing a particular case of the proposed technical solution.

The execution of the body of the anode earthing switch of ductile iron increases the resource, as it reduces the likelihood of destruction of the case by uneven ground displacement during operation, for example, due to freezing.

The execution of the body of the anode earthing switch of ductile iron allows you to make a hole in the wall of the housing in a technological way, for example, by machining, without causing destruction of the housing.

The presence of a through hole in the wall of the housing, in conjunction with the housing made of ductile iron, in conjunction with the location of the mechanical attachment point in the through hole and in conjunction with fixing the tip of the supply cable directly to the inner surface of the housing, improves the manufacturability of the production of the anode ground electrode, as it simplifies Compared with the closest analogue, the design of the mounting unit due to the possibility of eliminating the intermediate part, and also, as a result, eliminating weld about the connection of the intermediate piece to the housing; however, such an improvement in manufacturability does not lead to the risk of destruction of the casing due to loads arising from the use of some known mechanical fasteners (and known fastening methods).

The execution of the body of the anode earthing conductor from ductile iron makes it possible to perform flat sections on the surface of the housing around the through hole, characterizing a particular case of the proposed technical solution, in a technologically advanced way, for example, by machining without causing damage to the housing.

The implementation in the particular case of the proposed technical solution for the body of the anode earthing switch of high-strength cast iron with spherical graphite additionally increases the strength of the anode grounding due to the greater strength of cast iron with spherical graphite.

The implementation in the particular case of the proposed technical solution for the case of the anode ground electrode in the form of a pipe additionally reduces the cost of production of the anode ground electrode, since the execution of products in this form is widespread in industry and is high-tech and economical.

The implementation in the particular case of the proposed technical solution of the sections of the housing surface around the through hole, at least from the outside, by flat machining, in conjunction with the implementation of the mechanical fastener in the form of a bolt-nut connection or in the form of a rivet connection, additionally increases the resource (reliability ) and simplifies the high-quality assembly of the anode ground electrode, as it improves the electrical contact of at least the mechanical attachment point with the housing.

The isolation of the mechanical attachment point with the tip of the lead-in cable from the external environment with an epoxy compound layer and, if necessary, the heat-shrink sleeve in the particular case of the proposed technical solution increases the life of the anode ground electrode due to the prevention of the destruction of the cable end and attachment point due to corrosion.

Two figures are attached to the description, illustrating, by way of example, the implementation of the contact node (attachment node) of the proposed anode ground electrode and the principle of its use. On each of figures 1, 2, a fragmentary view of a case in the form of a pipe in a section along a plane formed by the axes of the case and a hole of a cylindrical shape in the wall of the case, and an installed contact assembly are simplified. In this case, FIG. 1 relates to a pipe of cylindrical shape or to a cylindrical section of a shaped pipe, and FIG. 2 relates to a bell-shaped part of a pipe with a bell.

As the bodies of the anode earthing switches, 3-meter-long cylindrical pipes cast from high-strength cast iron with spherical inclusions of graphite according to ISO 2531 without external and internal coating or painting, fragments of which 1 are shown in section in Fig. 1 and Fig. 2, are used. In Fig.2, the designations coincide with the designations in Fig.1. Through the marking, a through hole 2 with a diameter of 8 millimeters with a tolerance in free dimensions was drilled in the pipe wall. From the outside of the pipe 1 around the hole 2, the surface 3 is milled to form a flat portion 4 for a embedded copper washer 5. The electrical contact of the supply cable 6, 1 meter long, with the pipe 1 occurs through a copper flat terminal-tip 7 having a hole or notch, which mounted on cable 6 by soldering to the cable conductor. Terminal 7 is pressed against the inner surface 8 of the pipe 1 (a copper or tinned washer 9 can be located between the terminal 7 and surface 8, which does not change the essence of the technical solution, since the washers are standard parts of the bolt-nut fastening sets). The hole 2, the hole of the terminal 7, the washer 5 and, if available, the washer 9 are pierced with a tinned copper or steel bolt 10. From the inner side of the pipe 1, a copper or tinned nut 12 is screwed onto the shaft 11 of the bolt 10, pressing the terminal 7 to the inner surface of the pipe 8 1. The degree of tightening of the fastener assembly must ensure full compression of the pipe surfaces 1 with washers 5 and 9, or with terminal 7. The tightened fastener assembly (bolt 10, nut 12 and washers 5, 9) and terminal 7 with exposed section of cable conductor 6 are isolated from moisture by spraying or manually cysts th epoxy. The insulation areas in figures 1 and 2 are indicated by thick dashed lines.

Operated anode grounding as follows. In a pre-prepared recess on the ground, partially filled with coke breeze, an anode ground electrode is laid so that the free end of the supply cable protrudes above the surface level. After this, the anode ground electrode is covered with a layer of coke breeze, and then with a layer of soil flush with the surface. The protruding end of the cable is connected to the cable coming from one of the poles of the cathodic protection station, and the junction is isolated. The opposite pole of the cathodic protection station is connected by another cable to the protected object, for example, a pipeline located partially or completely in the ground. In the event of a leak in the electrical and waterproofing layer of the pipeline, an electric current in the thickness of the soil between the anode ground electrode and bare sections of the pipeline prevents corrosion of the bare sections.

The proposed anode earthing switches were manufactured by the applicant, while a reduction in production cost was achieved compared to the production of the closest analogue at the same production base. The operation of the proposed anode ground electrodes has revealed their increased reliability and strength.

The proposed anode grounding conductors can be used in the national economy and can be manufactured industrially.

Claims (5)

1. Anode earthing switch, comprising a hollow molten metal case as an electrode and a lead-in cable with a tip secured inside the case by means of a mechanical attachment unit, insulated with the tip of the lead-in cable from the external environment, characterized in that the case is made of ductile iron in the case wall a through hole is made, the attachment unit being installed in this through hole, and the tip of the supply cable is fixed directly to the inner surface of the housing. 2. Anode ground electrode system according to claim 1, characterized in that the housing is made of ductile iron with spherical graphite. 3. Anode ground electrode system according to claim 1 or 2, characterized in that the housing is made in the form of a pipe. 4. The anode ground electrode according to claim 1 or 2, characterized in that the surface sections of the housing around the through hole, at least from the outside, are made flat, and the fastening unit is made in the form of a bolt-nut connection or in the form of a rivet connection. 5. Anode ground electrode system according to claim 1 or 2, characterized in that the mechanical attachment point with the tip of the supply cable is isolated from the external environment by a layer of epoxy compound and, if necessary, a heat shrink sleeve.