RU5409U1 - SEALING THE OUTPUT OF CATHODE RODS OF ALUMINUM ELECTROLYZER - Google Patents

Abstract

The sealing of the output of the cathode rods of an aluminum electrolyzer, including a sealing seal around the cathode rod, made of self-hardening material, and attached to the cathode casing with windows for passing the cathode rods, a metal box with two holes, one of which is designed to pass the cathode rod, and the other to supply the self-hardening embedment material, characterized in that between the sealing embedment and the cathode rod is a layer of material that provides sliding of the cathode rod nya relatively tight seal.

Description

SEALING THE OUTPUT OF CATHODE RODS OF ALUMINUM ELECTROLYZER

The proposed utility model relates to the electrolytic production of aluminum, in particular, to the cathode devices of electrolytic cells for the production of aluminum, namely, to the design of the sealing of the output of the cathode rods.

Known seal output cathode rods of an aluminum electrolyzer, including a pipe connected to the cathode casing with windows for passage of the cathode rods, having a vertical bell facing the inside of the casing, and a sealing seal between the pipe and the cathode rod (Non-ferrous metals reference book. Aluminum production. - M .: Metallurgy, 1971, S.191-193.).

M. cl. S 25 S 3/08

The disadvantage of this seal is that during the firing and start-up of the aluminum electrolyzer and in the initial period of its operation, as a result of thermal expansion of the cathode rod, it moves relative to the sealing seal, which can lead to cracking in the sealing seal due to adhesion (adhesion) of the sealing material with cathode rod, as well as the formation of a gap between the cathode rod and the seal, thereby violating the tightness of the seal. Air, easily penetrating the cracks and the gap to the side coal lining, oxidizes and destroys it. This reduces the service life of the aluminum electrolyzer and quite often causes a breakthrough and leakage of the melt through the windows cut through the longitudinal walls of the cathode casing for passing the cathode rods. The presence of cracks in the sealing seal reduces its strength and in the process of further operation of the aluminum electrolyzer leads to its complete destruction. In addition, it should be noted the complexity and duration of the installation work associated with filling up the free space around the cathode rod.

The closest is the sealing of the output of the cathode rods of the aluminum electrolyzer, including a metal box with two holes attached to the cathode casing with windows for passing the cathode rods and a sealing seal around the cathode rod made of self-hardening material, while one of the holes of the box is designed to pass the cathode rod, and another for the supply of self-hardening sealing material (Application of France N 2535537, Н 02 G 15/013, Pub. 04.05.83).

The use of such a design of the sealing of the output of the cathode rods of the aluminum electrolyzer can significantly reduce the complexity and duration of the installation work by filling the free space around the cathode rod by filling. At the same time, the presence of a metal box prevents the complete destruction of the sealing seal.

However, this design of the seal does not exclude the possible formation of cracks in the sealing termination and the formation of a gap between the cathode rod and the termination due to the movement of the cathode rod relative to the sealing termination as a result of its thermal expansion during the firing and start-up of the aluminum electrolyzer and in the initial period of its operation. This violates the tightness of the output of the cathode rod, allowing air to easily penetrate through the cracks and the gap to the lateral coal lining. Air, penetrating the side coal lining, oxidizes and destroys it. This reduces the service life of the aluminum electrolyzer and quite often causes a breakthrough and leakage of the melt through the windows cut through the longitudinal walls of the cathode casing for passing the cathode rods.

The utility model is based on the task of creating a sealing of the output of the cathode rods of an aluminum electrolysis cell, ensuring the tightness of the output of the cathode rod by maintaining the integrity of the sealing seal when moving the cathode rod relative to the sealing seal as a result of its thermal expansion, which will increase the service life of the aluminum cell and eliminate leakage of the melt through windows for skipping cathode rods.

The achievement of the above technical result is ensured by the fact that in the seal of the output of the cathode rods of the aluminum electrolyzer, including a sealing seal around the cathode rod, made of self-hardening material, and connected to the cathode casing with windows for passing the cathode rods, a metal box with two holes, one of which is intended for the passage of the cathode rod, and another for supplying self-hardening material of the seal, between the sealing seal and the cathode rod is a layer material providing sliding sealing with respect to the cathode rod seal.

The location between the sealing termination and the cathode rod of the layer of material that allows the cathode rod to slide relative to the sealing termination allows the cathode rod to move freely relative to the sealing termination during its thermal expansion, which eliminates the formation of cracks in the sealing termination and ensures the sealing of the cathode rod output by maintaining the integrity of the sealing termination . This prevents the penetration of air to the side of the coal lining, thereby contributing to an increase in the service life of the aluminum electrolyzer, and also prevents leakage of the melt through the windows cut through the longitudinal walls of the cathode casing for passing the cathode rods.

Thus, the proposed sealing of the output of the cathode rods can increase the service life of the aluminum cell and eliminate leakage of the melt through the windows for the passage of the cathode rods.

The essence of the proposed utility model is illustrated by the drawing, which shows a vertical longitudinal section of the seal of the output of the cathode rods of an aluminum electrolyzer.

The sealing of the output of the cathode rods of the aluminum electrolyzer includes a metal box 2 connected to the cathode casing 1 and a sealing seal 3 around the cathode rod 4, withdrawn from the cathode casing 1 through the window 5. The metal box 2 is attached to the cathode casing 1 by welding. In this case, welding can be performed around the entire perimeter of the metal duct 2 or only in a few places. The metal box 2 is made with two holes 6, 7, while the hole 6 is designed to pass the cathode rod 4, and the hole 7 is for feeding self-hardening material 3. The sealing seal 3 is made of self-hardening material, which can be used fireclay dense concrete , silicon carbide concrete, shotcrete. Between the sealing seal 3 and the cathode rod 4 is a layer 8 of material that provides the sliding of the cathode rod relative to the sealing seal. As such material can be used, for example, oiled paper, polyethylene, polymer film, graphite suspension.

The industrial applicability of the sealing of the output of the cathode rods of an aluminum electrolyzer is confirmed by the above example of its practical implementation.

After installing the hearth sections, consisting of hearth blocks and cathode rods embedded in them, and passing the cathode rods through the windows in

the longitudinal sides of the cathode casing on the segments of the cathode rods in the places of their output from the cathode casing and the location of the sealing seal is applied a layer of material that provides sliding of the cathode rods relative to the sealing seal. As such material, oiled paper is used, fixed to the cathode rod using adhesive tape. Then, a metal box is installed on each cathode rod. The metal box is fixed to the cathode casing by welding. In this case, welds can be located either around the entire perimeter of the metal box, or only in a few places. After connecting to the cathode casing, the metal box is filled through the hole in it with a self-hardening sealing material. Chamotte dense concrete is used as the seal material. Filling the metal box with self-hardening material, in this case, chamotte dense concrete, is performed manually, followed by vibrational compaction of the material. It is possible to fill the metal box with self-hardening material through the hole in it using pressure devices.

During thermal expansion of the cathode rods during the firing and start-up of the aluminum electrolyzer and during the initial period of its operation, the presence of a layer of material between the sealing seal and the cathode rods that ensures the sliding of the cathode rods relative to the sealing seal allows cathode rods to move freely relative to the sealing seal, which eliminates the formation of cracks in sealing termination and ensures the tightness of the output of the cathode rods by maintaining the integrity of the sealing termination. This provides an increase in the service life of the aluminum electrolyzer and eliminates leakage of the melt through the windows cut through in the longitudinal walls of the cathode casing for passing the cathode rods.

Using the design of the proposed seal will allow the electrolyzer with a current of 156 kA with a self-baking anode to increase the average life by 4 months.

Claims (1)

The sealing of the output of the cathode rods of an aluminum electrolyzer, including a sealing seal around the cathode rod, made of self-hardening material, and attached to the cathode casing with windows for passing the cathode rods, a metal box with two holes, one of which is designed to pass the cathode rod, and the other to supply the self-hardening embedment material, characterized in that between the sealing embedment and the cathode rod is a layer of material that provides sliding of the cathode rod nya relatively tight seal.