RU2396373C1 - Anode earthing device and method of its installation - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention refers to electrochemical protection of underground structures against corrosion and can be used during construction of anode and working DC earthings. Anode earthing device differs by the fact that the electrode arranged in lower part is equipped with additional current lead with additional current-conducting wire; connections of electrodes are tightly enveloped with flexible cup made from dielectric material. Upper and lower electrodes are equipped from above and from below respectively with flexible caps made from dielectric material with holes for the main and additional current-conducting wires; lower electrode is equipped with process branch pipe equipped with a guide for the lowering device of the lifting mechanism. Invention also refers to installation method of anode earthing device including the bottom-up assembly of electrodes one above the other to the electrode with current-conducting wire, lowering to vertical well (bore hole) by means of the lowering device (rope, wire rope, cable) of the lifting mechanism with further filling of the bore hole with anode earthing in the central part with electroconductive substance, and from above - with coarse-porous loose material.

EFFECT: invention allows simple assembling and arranging from the surface in the bore hole during installation of anode earthing device by minimising the possibility of electrode contacts fouling, and ensuring the monitoring of anode earthing device condition.

4 cl, 1 dwg

Description

The invention relates to the field of electrochemical protection of underground structures against corrosion and can be used in the construction of anode and working grounding DC.

The well-known "Anode ground electrode" (patent RU No. 1226561, H01R 04/66, publ. Bull. No. 12 of 04/23/1986), containing electrodes sequentially mounted on top of each other, having a cylindrical cavity with a conical entrance at the lower end, the upper the conical end of the electrode enters the cavity of the upstream electrode and forms a point or linear contact with the surface of the cavity, and an electrode with a current lead located in the integral part of the electrode cavity.

The installation method of this ground electrode system is carried out from the bottom up, sequentially lowering it into a vertical well (pit) and installing one above the other to the electrode with the current lead, followed by filling the hole with the ground electrode in the central part with an electrically conductive substrate, and on top with coarse-grained bulk material.

The disadvantages of this ground electrode system are insufficient reliability due to the possibility of damage during transportation and assembly of the pointed ends of the electrodes (especially electrodes made of brittle sparingly soluble metal, such as ferrosilide), which leads to poor contact and the inability to place the current lead in a waterproof cavity, which leads to its rapid anodic dissolution. In this case, the upper electrodes, the places of contact of the electrodes with each other and between the upper electrode and the conductive wire are most intensively dissolved, which leads to premature failure of the entire anode ground electrode. It is also impossible to monitor the state of the anode ground electrode.

The disadvantages of the installation method of the ground electrode system are the difficulty of joining the electrodes (especially the lower ones), the high probability of contact with the walls of the pit and the ingress of soil into the contact zone of the electrodes and, as a consequence, a decrease in the quality of protection of underground structures.

The closest in technical essence and the achieved result is "Anode earthing" (patent RU No. 2294584, H01R 04/66, publ. Bull. No. 6 of 02.27.2007), including poorly soluble electrodes mounted on top of each other, having at the bottom end a cylindrical cavity with a conical inlet, and the upper end of each electrode enters the cavity of the upstream electrode and forms a linear or point contact with the surface of the cavity, an electrode with a current lead located in the integral part of the electrode cavity, and a conductive wire connected the electrode through the current lead, while the electrodes are made with a thickening in the zone of the cavity, 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 entrance of the cavity of the upstream electrode, and the upper end of the electrode located below electrode with a current lead, equipped with a pointed tip in contact with the surface of the consolidated part of the cavity of the electrode with the current lead.

The installation method of this ground electrode system is carried out from the bottom up, sequentially lowering it into a vertical well (pit) and installing one above the other to the electrode with the current lead, followed by filling the hole with the ground electrode in the central part with an electrically conductive substrate, and on top with coarse-grained bulk material.

The disadvantages of the proposed installation method is the difficulty of joining the electrodes (especially the lower ones), the high probability of contact with the pit walls and the ingress of soil into the contact zone of the electrodes and, as a consequence, a decrease in the quality of protection of underground structures.

The disadvantages of this earthing switch are the insufficient possibility of sequential mounting on the surface with subsequent descent into the pit and low reliability due to the insecurity of the electrode contacts from clogging, especially from falling during the descent of the soil, which leads to premature failure of the entire earthing switch. In this case, the upper electrodes, the places of contact of the electrodes with each other and between the upper electrode and the conductive wire dissolve most intensively during use, which leads to premature failure of the entire anode ground electrode. It is also impossible to monitor the state of the anode ground electrode.

An object of the invention is to provide an anode earthing switch that is simple to assemble and install and reliable when applied by using a simple method of assembling electrodes from the surface of the pit, minimizing the possibility of clogging of the electrode contacts when they are lowered into the pit, with more uniform dissolution of the electrodes due to dielectric protection material of the junctions of the electrodes and the junctions of the upper and lower electrodes with the conductive wire, as well as providing control over the state of the anode ground during use, by connecting both the top and bottom to the anode grounding conductor conductive wires.

The technical problem is solved by an anode ground electrode, including 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 an expansion with a cylindrical cavity and a conical butt surface at the lower end, the upper end of each electrode entering the cavity the upstream electrode, is configured to interact with the conical butt surface with the formation of a linear or point contact.

New is that the electrode located in the lower part is equipped with an additional current lead with an additional conductive wire, and the electrode connections are sealed by an elastic cuff made of dielectric material, while the upper and lower electrodes are equipped with elastic caps made of dielectric material with holes for the main and additional conductive wires, and the lower electrode is equipped with a technological branch pipe equipped with a guide for lifting device descent.

Also new is the fact that the process pipe is made in the form of a cup placed on the bottom electrode, and its guide is in the form of a through hole with a groove for the descent device of the lifting mechanism.

Also new is the fact that the technological pipe is made in the form of a cup placed on the bottom electrode, and its guide is in the form of a through hole with one or more rollers for the lifting device of the lifting device.

The technical problem is also solved by the method of installing an anode ground electrode system, including assembling the electrodes from the bottom up above one another to an electrode with a conductive wire, lowering it into a vertical well using a lifting mechanism descent device, and then filling the pit with the anode ground electrode in the central part of the electrically conductive substrate, and on top of the large-porous bulk material.

What is new is that before starting the descent, all the upper parts of the electrodes except the upper are equipped with elastic cuffs, and the descent device of the lifting mechanism is inserted into the guide of the technological pipe, followed by lowering into the pit to a depth sufficient to install a lower electrode equipped with an elastic cap and an additional bottom conductive wire, then the assembled element with an additional wire is lowered onto the installed electrode, put on the next electrode, tightly putting on it with outside the elastic cuff, similarly collect all the electrodes of the anode ground electrode, then put the upper elastic cap on the upper electrode with the conductive wire and lower the anode ground electrode on the descent device of the lifting mechanism until it stops at the bottom of the pit, after which the descent device is disconnected from one end and removed by a lifting mechanism to the surface.

The drawing shows an anode ground electrode installed in a vertical well (pit).

The anode ground electrode system includes an upper electrode 1 with a current lead 2 and a conductive wire 3 connected to the electrode 1 through a current lead 2, sparingly soluble electrodes 4, having an extension 5 with a cylindrical cavity 6 and a conical butt surface 7 at the lower end, the upper the end 8 of each electrode 4 included in the cavity 6 of the upstream electrode 4 is configured to interact with the conical butt surface 7 with the formation of a linear or point contact. The electrode 9, located in the lower part, is equipped with an additional current lead 10 with an additional conductive wire 11 connected by an additional current lead 10 to the lower electrode 9. The connections of the electrodes 1, 4 and 9 are hermetically enclosed by an elastic sleeve 12 made of a dielectric material. The upper 1 and lower 9 electrodes, respectively, above and below the elastic upper 13 and lower 14 caps of dielectric material with holes 15 under the main 3 and an additional 11 conductive wires. Bottom of the lower electrode 9 is equipped with a technological pipe 16 equipped with a guide 17 for a descent device (rope, cable, cable - not shown) of the lifting mechanism (winch, drum with a drive - not shown).

Technological pipe 16 can be made in the form of a pipe 16 mounted on the bottom electrode 9 from the bottom, and its guide 17 - in the form of a through hole with a groove 18 for the lifting device of the lifting device.

Technological pipe 16 can be made in the form of a pipe 16 mounted on the bottom electrode 9 from the bottom, and its guide 17 - in the form of a through hole with one or more rollers (not shown in the drawing) under a lifting device for reducing the friction.

The installation method of the anode ground electrode is implemented as follows.

Pre-prepare vertical wells (pits - not shown) of the required depth for anode grounding conductors. All the upper ends 8 of the electrodes 4 and 9, except the upper 1, are equipped with elastic cuffs 12. A descent device (rope, cable, cable) of the lifting mechanism is inserted into the guide 17 of the process pipe 16, followed by a descent into the pit to a depth sufficient to install the lower electrode 9 with an additional 11 conductive wire, previously equipped with an elastic cap 14. The assembled element with an additional wire 11 is lowered, the next electrode 4 is put on the installed electrode 9, tightly donning I it outside with an elastic cuff 12. Similarly, bottom-up collect all the remaining electrodes 4 1 and Anode. After that, the upper elastic cap 13 is put on the upper electrode 1 with the conductive wire 3. The anode ground electrode is lowered as far as it will go to the bottom of the pit on the descent device that slides along the groove 18 or the rollers of the lifting mechanism. The descent device is disconnected from one end and removed by a lifting mechanism to the surface of the pit. Then, the anode ground electrode is centered relative to the pit, which is filled with an electrically conductive substrate (water, clay, mortar, earth pulp, coconut fines, etc. - not shown), and on top - with large-pore loose material (gravel, pebbles, etc. - not shown). Thanks to this installation of electrodes 1, 4, and 9, the contact points of these electrodes are tightly pressed together during the descent under the weight of the electrodes 1 and 4 themselves, and the elastic coupling does not allow clogging of the contact points of the electrodes 1, 4, and 9. All this together increases the reliability of the contact connection electrodes 1, 4 and 9 and, as a consequence, the passage of current.

After installation, the main 3 and additional 11 conductive wires are supplied with the necessary voltage with the current passing through the electrodes 1, 4 and 9 of the anode ground electrode. Part of the current from electrodes 1, 4, and 9 flows into the ground through an electrically conductive substrate, protecting the nearby underground structures from corrosion. In this case, the material of the electrodes 1, 4 and 9 located outside the elastic cuffs 12 and the upper 13 and lower 14 caps will dissolve, and the places protected by the elastic cuffs 12 and the upper 13 and lower 14 caps, which are made of dielectric material, will not, which eliminates the dissolution of the contact points of the electrodes 1, 4 and 9 and the junction of the upper 1 and lower 9 electrodes with the corresponding conductive wires 3 and 11, which significantly increases the uniformity of dissolution of the electrodes 1, 4 and 9 and, as a result, the service life of the entire anode gap mlitelya. The design with the main 3 and additional 11 conductive wires allows you to more evenly distribute the current along the entire length of the anode earthing switch, as well as monitor the state of the anode earthing switch: an increase in voltage and a decrease in current in the anode earthing switch indicates that the contact between the electrodes 1, 4 or 9 is insufficient or with current of time, the anode earthing switch is fully developed and it is necessary to carry out repair work of the anode earthing switch or replace it.

This invention allows you to simply collect and place from the surface in a pit when installing the anode ground electrode, minimizing the possibility of clogging of the contacts of the electrodes in this case. Moreover, the anode earthing switch is reliable in use, since the electrodes dissolve more evenly due to the protection of the cuffs of the joints of the electrodes and caps of the joints of the upper and lower electrodes with the conductive wire with dielectric materials. The anode earthing switch also provides control over the state of the anode earthing switch during use due to the connection of conductive wires to and above and below it.

Claims (4)

1. Anode earthing switch, 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 an expansion with a cylindrical cavity and a conical butt surface at the lower end, the upper end of each electrode entering the cavity upstream the electrode is configured to interact with the conical butt surface with the formation of a linear or point contact, characterized in that the electrode is placed in the lower part, is equipped with an additional current lead with an additional conductive wire, and the electrode connections are sealed by an elastic cuff made of dielectric material, while the upper and lower electrodes are equipped with elastic caps of dielectric material with holes for the main and additional conductive wires, respectively, above and below the lower electrode is equipped with a technological branch pipe equipped with a guide for the lowering device of the lifting mechanism. 2. The anode ground electrode according to claim 1, characterized in that the process pipe is made in the form of a cup placed on the bottom electrode, and its guide is in the form of a through hole with a groove for the lifting device of the lifting device. 3. The anode ground electrode according to claim 1, characterized in that the process pipe is made in the form of a cup placed on the bottom electrode, and its guide is in the form of a through hole with one or more rollers for the lowering device of the lifting mechanism. 4. A method of installing an anode ground electrode system, including assembling the electrodes from bottom to top one above the other to an electrode with a conductive wire, lowering it into a vertical well using a lifting mechanism descent device, and then filling a hole with an anode ground electrode in the central part with an electrically conductive substrate, and with a porous bulk material on top , characterized in that before the descent, all the upper parts of the electrodes except the upper are equipped with elastic cuffs, and in the guide of the technological pipe in the descent device of the lifting mechanism is pressed down, followed by a descent into the pit to a depth sufficient to install a lower electrode equipped with an elastic cap and an additional conductive wire from below, then the assembled element with an additional wire is lowered, the next electrode is lowered, tightly putting on it from the outside in this case, the elastic cuff, similarly collect all the electrodes of the anode ground electrode, the field of which on the upper electrode with a conductive wire put on the upper elastic cap and lower the anode ground electrode on the descent device of the lifting mechanism until it stops at the bottom of the pit, after which, before filling the pit, the descent device is disconnected from one end and removed by the lifting mechanism to the surface.