RU2348743C2 - Cathodic current-carrying rod of aluminium electrolyser - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: invention concerns production of aluminium by electrolysis of molten salts. Particularly it concerns structure of cathodic current-carrying rod. Cathodic current-carrying rod contains metallic rod with internal cavity and bush made of material with high specific conductance, fixed in internal plane with ability of electric contact with metal rod. Bush is implemented from metal with melting temperature lower than electrolysis operating temperature, not interacting with material of metallic rod and providing electric contact of bush with internal surface of metallic rod during metal melting. Bush can be implemented of magnesium or calcium. Bush can be implemented as variable in transversal section by its length by means of installation of metallic insertions in internal cavities of metallic rod. It is provided electrolyser consistency of operation by means of heterogeneity reduction of vertical stream by surface of cathodic section, increasing of cathode assembly durability of aluminic electrolyser at the expense of wear uniformity of carbon-bearing cathodic blocks.

EFFECT: providing of electrolyser consistency of operation at the expense of vertical stream by surface of cathodic section, increasing of cathode assembly durability of aluminic electrolyser at the expense of wear uniformity of carbon-bearing cathodic blocks.

3 cl, 4 dwg, 1 ex, 1 tbl

Description

The invention relates to the field of non-ferrous metallurgy, to the production of aluminum by electrolysis of molten salts, in particular to the design of a cathode current-carrying rod.

The cathode current-carrying rod is designed to remove electric current from the cathode and transfer it to the external busbar, through which it enters the next electrolyzer. An electric current enters the cell through the anodes, passes through the layers of electrolyte and metal, and then enters the cathode of the aluminum cell.

The cathodic current-carrying rod, usually made of steel, is fixed in the groove of the carbon-containing cathode block using electrically conductive material (cast iron, carbon paste or carbon glue). Carbon-containing cathode blocks with installed cathode current-carrying rods are called cathode sections, a group of which forms the cathode of an aluminum electrolyzer.

A known cathode section of an aluminum electrolyzer, including a cathode carbon block with a cathode current-conducting rod fixed in it by means of cast iron, which is made in the form of two elements of the same cross section rigidly interconnected, and the part of the rod located under the anode is made of copper, and the outer part is from steel (patent SU 1260412, class C. С25С 3/08, 1986).

One of the main drawbacks of this technical solution is that the copper part of the cathode current-carrying rod does not have a continuous protective sheath that impedes air access and copper oxidation at high temperatures, in addition, with increasing temperature, copper strength significantly decreases. All of the above leads to an increase in the contact resistance of the carbon block - the cathode current-carrying rod, and, accordingly, will lead to an increase in the voltage drop in the cathode of the electrolyzer.

Another disadvantage of the invention are the difficulties that arise when creating the connection "copper part - steel part" of the cathode current-carrying rod with an acceptable level of voltage drop in it. The problems associated with the difference in the thermal expansion coefficients of copper and steel, the high oxidizability and low strength of copper at temperatures close to the working temperature of electrolysis and the high temperature of the region of the connection of copper and steel, do not allow to obtain a good connection.

These shortcomings explain the relatively low performance obtained by testing the proposed cathode section.

Similar drawbacks have cathodic current-carrying rods according to the patents US 2846388, 1956, US 3551319, 1970.

The closest to the invention in terms of technical nature and the effect achieved is a cathode current-carrying rod installed in a groove of the carbon-containing cathode block of the cathode device of an aluminum electrolyzer, including a metal rod (steel) with an internal cavity and an insert made of a material with high electrical conductivity (copper) installed in the internal cavities with the possibility of electrical contact with the rod. The inner cavity in the cathode current-carrying rod is made from the side of its inner end does not reach the outer end, and has a polygonal profile or a round profile in cross section (patent RU No. 2239007, IPC С25С 3/08, 2004).

The main disadvantages of this invention include technological difficulties in the manufacture of the inner cavity for the liner and the liner itself in the cathode current-carrying rod. To create good electrical contact along the entire length of the cathode current-carrying rod, high precision processing of products is required, or complex technological equipment is required to press the copper core into the steel current-carrying rod. But even in this case, it is extremely difficult to ensure good electrical contact at a cathode rod temperature of ~ 850 ÷ 960 ° C over a length of several meters. Another disadvantage of the prototype is a significant increase in the cost of the cathode section due to the addition of a copper insert with a high cost, since the length of the insert is from 1.0 to 1.4 m with a cross-sectional area of the insert 5-30% (sometimes up to 70%) of the cross section steel current-carrying rod. In the case of using a copper insert with a smaller cross section, there is no noticeable equalization of the degree of heterogeneity of the vertical current along the length of the carbon-containing cathode block and the voltage drop in the cathode current-carrying rod does not decrease.

The objective of the invention is to reduce the voltage drop in the cathode block to reduce energy consumption, simplify and cheapen the design of the cathode current-carrying rod by reducing the requirements for precision manufacturing of the inner cavity of the rod and the liner, and the use of less expensive materials, increasing the service life and stability of the cell by reducing the degree of heterogeneity of the vertical current on the surface of the carbon-containing cathode block.

The technical result consists in reducing the voltage drop in the carbon-containing cathode block due to the development of a design of a cathode current-carrying rod, which is simple in manufacturing, and which allows to significantly increase the effective electrical conductivity of the latter. This ensures low electrical contact resistance between the inner cavity of the metal rod and the liner with high electrical conductivity along the entire length of the cathode current-carrying rod.

To solve the problem in the design of the cathode current-carrying rod, designed to be installed in the groove of the carbon-containing cathode block of the cathode device of an aluminum electrolyzer, including a metal rod with an internal cavity and an insert made of a material with high electrical conductivity, installed in the internal cavity with the possibility of electrical contact with a metal rod, according to the claimed invention, the liner is made of metal with a melting point below the operating temperature electrolysis, not interacting with the material of the metal rod and providing electrical contact of the liner with the inner surface of the metal rod when melting the metal of the liner.

This design of the cathode current-carrying rod allows to significantly reduce the voltage drop in the cathode current-carrying rod, in the carbon-containing cathode block as a whole, and thereby reduce the energy consumption consumed by the electrolyzer. In addition, an increase in electrical conductivity can reduce the degree of heterogeneity of the distribution of vertical current over the surface of the cathode block and, thereby, reduce the unevenness of wear and, accordingly, increase the service life and stability of the aluminum electrolyzer.

The liner of the cathode current-carrying rod can be made of magnesium or calcium.

A metal insert with a bevel can be installed in the inner cavity of the metal rod, with the massive part of the insert directed to the outward part of the cathode rod, the rest of the inner cavity of the metal rod can be filled with the metal of the insert with the formation of a variable cross-sectional length of the insert.

That allows you to align the degree of heterogeneity of the vertical current on the surface of the cathode section. Thus, the effective conductivity along the length of the cathode current-carrying rod becomes differentiated: minimum in the protruding outward part of the rod and maximum in the part of the rod installed in the center of the cathode block.

To ensure a significant increase in the electrical conductivity of the cathode current-carrying rod, any metals can be used (not just copper χ = 9900000 [Ohm · m] ^-1 ) with a specific conductivity exceeding the conductivity of steel at working electrolysis temperatures of 930-970 ° C (860000 [Ohm · m ] ^-1 ), for example: magnesium 2278000 [Ohm · m] ^-1 , calcium 2380000 [Ohm · m] ^-1 .

At a working temperature of 930-970 ° C, all of the proposed metals for the liner (magnesium, calcium) will be in a molten state. Their advantage is that they do not form alloys with steel. In addition, these metals have another advantage - low density, since the density of magnesium is 1.74 g / cm ³ , calcium 1.55 g / cm ³ in contrast to copper 8.89 g / cm ³ , and lower cost. For example, in order to obtain a 3-fold increase in the electrical conductivity of the cathodic current-carrying rod, it is necessary to use a copper insert, which is ~ 24% of the cathode rod volume, in the case of a magnesium insert ~ 63%, and calcium ~ 60%. The table provides comparative estimates of the share of the cost of the liner in the total cost of the cathode current-carrying rod using the example of a cathode rod of size 1900 × 80 × 180 mm and a liner with a high conductivity of 1000 mm in length.

Options Liner material Copper (Cu) Magnesium (Mg) Calcium (Ca) The component of the insert from the cross section of the cathode rod,% 24 62 60 The mass of the liner, kg 30.7 15,5 13,2 Cost, rub / kg (according to the 1st quarter of 2007) 162 54 108 Total rub 4973 837 1426

The invention is illustrated by the following drawings. Figure 1 shows a General view of an aluminum electrolyzer, a cross section; figure 2 presents the cathode section of the cell with the proposed cathode current-carrying rod, conventionally shown with a cut; figure 3 shows the cathode section with a cathode current-carrying rod made in accordance with paragraph 3 of the claims, conventionally shown with a cutout, figure 4 shows the temperature dependence of the electrical resistivity of some designs of cathode current-carrying rods.

The cathode current-carrying rod 1 includes a metal rod 2 with an internal cavity 3, a liner 4 made of a material with high electrical conductivity, with a melting point below the working temperature of electrolysis and installed in the internal cavity 3 with the possibility of electrical contact with a metal rod 2, the ends of which are closed by metal plates 5 and in the protruding part 6 there is an outlet 7 for air outlet. The proposed cathodic current-carrying rod 1 is intended for installation in a carbon-containing cathode block 8, made with a groove 9 by fixing the rod 1 with an electrically conductive material 10 (cast iron, carbon paste or carbon glue). Carbon-containing cathode blocks 8 with installed cathode current-carrying rods 1 are called cathode sections 11, the group of which forms the cathode 12 of the aluminum electrolyzer.

To substantially equalize the vertical current along the surface of the cathode section 11, it is proposed to make an insert 4 with a cross section variable along the length of the cathode current-carrying rod 1 by installing metal inserts 13 in the inner cavity 3 of the metal rod 2.

The cathode current-carrying rod 1 operates as follows: an electric current enters the electrolyzer 14 through the anode bus 15 and anodes 16, passes through the layers of electrolyte 17 and metal (aluminum) 18 and enters the cathode 12 of the aluminum electrolyzer, consisting of cathode sections 11, from there it is removed by the cathode current-carrying rods 1 connected by flexible aluminum slopes 19 with the cathode bus 20 and then through it enters the next cell (not shown conditionally).

To evaluate the proposed technical solution, experimental studies of samples of cathodic current-carrying rods were carried out, during which the values of electrical resistivity were measured. For this, the following samples were used: a steel bar with a diameter of 27 mm, a steel pipe with an external diameter of 27 mm and a diameter of the inner cavity of 22 mm, into which a magnesium insert was placed. Tests were carried out to maximum temperatures of ~ 1000 ° C, moreover, repeatedly, while the samples constantly showed repeatability of the results.

The results of the tests (figure 4) show that the electrical resistivity of the proposed cathode rod at operational temperatures is almost 3 times lower than steel.

Checking the electrical resistance at the interface between magnesium and steel in the sample shows the presence of a low contact resistance of not more than 10 ^-10 Ohm · m ² .

A sample with a magnesium insert was cut to view the interface between magnesium and the inner surface of the steel rod and found that the surface of the steel was well moistened with magnesium and it fits snugly against the wall. No traces of their interaction and the formation of intermetallic compounds were found.

Design example: A magnesium or calcium rod of the appropriate size is placed in a steel rectangular pipe 1840 × 80 × 180 mm in size with a wall thickness of 12 mm, after which the ends of the pipe are welded with metal plates 180 × 80 × 30 mm in size, but a small outlet remains in the protruding part pipes. After that, the metal cathode rod is heated to a temperature of 970 ° C, the hole is welded and the rod is cooled. There is another option: a metal current-carrying cathode rod with a magnesium or calcium rod placed is installed in the cathode section and, during the firing of the electrolyzer cathode (external heat sources - flame firing), magnesium or calcium is melted, thereby providing electrical contact between the liner and the inner surface of the metal rod, if there is excess magnesium or calcium, they are squeezed out through the outlet.

In the case of the use of cathode blocks with a high graphite content of 80-100% or fully graphitized (heat treatment up to 3000 ° C) with a low electrical resistivity of 8-18 μOhm · m in the design of the cathode device of the electrolyzer, it may be necessary to equalize the degree of heterogeneity of the vertical current on the surface of the cathode section. This can be done by installing inside a steel rectangular pipe 1840 × 80 × 180 mm in size with a wall thickness of 12 mm, a steel metal insert with a bevel of 1800 mm long, 56 mm wide and 0 to 80 mm high, with the massive part of the insert pointing towards outward part of the cathode rod. Magnesium or calcium rods of the appropriate size are placed in the remaining internal cavity, after which the ends of the pipe are welded. Thus, the effective conductivity along the length of the cathode current-carrying rod changes, it becomes minimal in the outward protruding part of the rod and maximum in the part of the rod installed in the center of the cathode block.

It should be specially noted that the technical solution proposed in this patent can be used not only on rectangular pipes, as shown in the example, but also on square, round, flattened (oval) or profile pipes.

The present invention allows to reduce the energy consumption in an aluminum electrolyzer by 300-400 kW / h t A1 by reducing the voltage drop in the cathode section by 90-120 mV, namely in the cathode current-carrying rod, to reduce the cost of the cathode current-carrying rod with a magnesium or calcium insert in 2 -4 times relative to the rod with a copper liner due to the simplification of the design of the cathodic current-carrying rod and the cost reduction of the materials used (metals).

At the same time, conditions are provided for stable operation of the electrolyzer by reducing the degree of heterogeneity of the vertical current along the surface of the cathode section, which, in addition, allows to increase the service life of the cathode device of the aluminum electrolyzer due to the uniformity of wear of carbon-containing cathode blocks.

Claims (3)

1. The cathode current-carrying rod, designed to be installed in the groove of the carbon-containing cathode block of the cathode device of an aluminum electrolyzer, including a metal rod with an internal cavity and an insert of material with high electrical conductivity, installed in the internal cavity with the possibility of electrical contact with a metal rod, characterized in that the liner is made of metal with a melting point below the working temperature of electrolysis, which does not interact with the material of the rod and insert providing electrical contact with the inner surface of the metal bar during the melting of the metal insert. 2. The cathode current-carrying rod according to claim 1, characterized in that the liner is made of magnesium or calcium. 3. The cathode current-carrying rod according to claim 1, characterized in that a metal insert with a bevel is installed in the inner cavity of the metal rod, the massive part of the insert being directed to the outgoing part of the cathode rod, the rest of the inner cavity of the metal rod is filled with the insert metal to form an alternating the length of the cross section of the liner.

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