RU2093611C1 - Method of automatically controlling feed of aluminum electrolyzer using silica - Google Patents

Abstract

FIELD: aluminum production. SUBSTANCE: silica is portionwise fed onto electrolyte surface in the regions with open surface without piercing crust. Amount of silica delivered in these regions is raised as compared to regions with cryolite-silica crust. In the regions having such crust and increased accretion volume, amount of delivered silica is diminished as compared to regions with open electrolyte surface. Weight of silica portion fed onto crust or electrolyte surface is 0.05-0.19 kg and feeding periodicity is 20-400 s. EFFECT: enhanced efficiency of process. 4 cl, 1 dwg, 1 tbl

Description

 The invention relates to the metallurgy of light metals, in particular to an electrolytic method for producing aluminum, and is aimed at improving the supply of alumina to the molten electrolyte and maintaining the technological parameters of electrolysis.

 One of the closest in technical essence is the known method and device for automatically feeding alumina to aluminum electrolysis cells, according to which a crust is punched with one or more hammers and a portion of alumina preloaded at appropriate points on the crust is introduced into the bath. After punching in areas under the hammers, reloading of alumina is performed. The crust is destroyed after 15 to 20 minutes, preferably from 20 to 45 minutes, alternately from one or the other side of the cell. A thicker layer of alumina is charged under the crust punching hammers to prevent the formation of thick electrolyte crusts. Under the crust punching hammers there are devices for the accumulation of alumina located on the crust.

 Another, closest in technical essence is the known method for automatically feeding aluminum electrolysis cells with alumina, including the use of stationary punches and metering devices installed on each electrolyzer, characterized in that, in order to stabilize the temperature and concentration of alumina in the electrolyte, alumina is fed into the electrolyte every 2 6 minutes in portions of 1 3 kg with preheating of each portion on the electrolyte crust.

 The general disadvantages of the known methods include the following.

 The known methods do not provide a continuity mode for the supply of alumina to the electrolyte and its distribution in the volume of the electrolyte, since the frequency of crust destruction and the supply of alumina to the melt, comprising 15-20 minutes and 2-6 minutes, leads to wetting by liquid electrolyte. The subsequent operation of the punching devices leads to immersion of the working bodies in the melt, re-enriched with alumina, and agglomeration of the melt (mixture) on the punches, which complicate their operation and reduce the portion of alumina dissolved in the electrolyte. On the other hand, for electrolyzers with a Soderberg anode, in particular of medium and high power, for several reasons, there are local areas of the electrolyte surface in the “anode” space, where a cryolite-alumina crust does not form, the temperature and melt circulation rate are higher than average electrolyzer. In this case, the operation of the punching devices on the punching of a nonexistent crust causes harm, since the melt sticks to the punch and disables it, the device fails, its increased wear. As a result, all this leads to an increase in the productivity of the electrolyzer, aluminum grading, loss of raw materials, electricity and an increase in labor costs. In this case, the region of the cell having such favorable conditions for dissolution as a more intense heat and mass transfer regime is not used for the active dissolution of alumina.

 Finally, such sections of the electrolyzer having more intense heat and mass transfer have a correspondingly reduced volume accrued. Therefore, a more intensive mode of cooling the melt is required, for example, by increasing the feed rate of the amount of introduced alumina per unit time, which is not possible with known methods and devices.

 And vice versa, in areas of the electrolyzer having a relatively increased volume of pressure, it is necessary to reduce the amount of alumina introduced per unit time, which the known methods and devices also do not implement.

 The purpose of the invention is to increase the productivity of the electrolyzer, the grade of the obtained aluminum, reducing the consumption of electricity, raw materials and labor.

 This goal is achieved by the fact that on an aluminum electrolyzer equipped with an automatic alumina feeding device, with a periodic supply of dosed portions of alumina to the crust, forcing the crust in local areas of the “board anode” space in the projection of supplying portions of alumina, in portions of the open surface of the electrolyte, portions of alumina are fed on the surface of the electrolyte and the crushing of the crust is not carried out. Moreover, in areas of the open surface of the electrolyte, the dosage of portions of alumina is increased in comparison with areas of the “board anode” space having a cryolite-alumina crust; in the areas of the “board anode” space having a cryolite-alumina crust and the volume increased have fallen, the dosage of portions is reduced in comparison with areas with an open electrolyte surface. In this case, portions of alumina are fed to the crust or to the surface of the electrolyte weighing 0.05 0.19 kg with a frequency of 20,400 s.

 The presence of an open surface of the electrolyte eliminates the need for crushing the crust, despite the fact that the need and possibility of supplying dosed portions of alumina to the electrolyte remains. In addition, the immersion of the working body of the punching device in liquid electrolyte prevents the dissolution of the material of the punch in the electrolyte and the sticking of the electrolyte-alumina mixture on the punch. As a result, the grade of aluminum increases, the operability of the device due to lowering the temperature of the punch and the overhaul period increases, as well as the productivity of the electrolyzer due to equalization of the concentration of alumina in the volume of the electrolyte and equalization of the temperature of the latter.

 An increase in the dosage of portions of alumina in areas of the open surface of the electrolyte compared to areas of the “anode” space having a cryolite-alumina crust allows the use of zones of increased heat and mass transfer to qualitatively dissolve as much alumina as possible and better average its concentration in the electrolyte volume.

 As a result, the productivity of the electrolyzer increases, the power consumption decreases due to a decrease in the frequency of anode effects. Stabilization of the process allows to reduce the consumption of fluorine-containing raw materials.

 A decrease in the dosage of portions of alumina in portions of the board-anode space having a cryolite-alumina crust and an increased volume accrued in comparison with areas with an open electrolyte surface makes it possible to create conditions for decreasing the volume of accretion to the optimal leveling size across the entire length of the bead. The amount of alumina deposits formed on the bottom also decreases. As a result, the productivity of the electrolyzer increases, the consumption of electricity, the loss of raw materials and the labor required to maintain the accretion are reduced.

The mass of portions of alumina 0.05 0.19 kg, supplied to the crust or to the surface of the electrolyte with a frequency of 20 400 s, were obtained experimentally and are due to the following circumstances:
a decrease in the mass of a portion of the supplied alumina improves the conditions for its qualitative dissolution in the electrolyte without the formation of sediment and an increase in the volume of accretion, and an increase in the frequency of operation of the dosing device is required;
a decrease in the mass of a portion of alumina and an increase in the frequency of the supply of portions makes it possible to effectively dissolve large volumes in areas with open electrolyte;
a decrease in the mass of a portion of alumina and an increase in the frequency of supply of a portion to the melt in areas with cryolite-alumina crust and increased sizes of nastily allows you to equalize the volume and size of nastily along the entire length of the electrolyzer, to avoid an excessive increase in the size of nastily, leading to failure of the device, disruption of electrolyte circulation and reduction technical and economic indicators.

 The invention is illustrated by the drawing (Fig. 1 and Fig. 2), which shows a variant of the device that allows to implement the proposed method.

 The device contains punches 1 driven by pneumatic cylinders 2 of one and the other longitudinal sides of the electrolyzer 3, a metering device 4 (fragment), which allows changing the size of a single portion of the alumina supplied to the melt, a pneumatic actuator control unit 5 controlled from the lower level 6 of an automatic process control system. Changing the parameters is set programmatically from the upper level 7 (VU) by means of, for example, an IBM computer, shut-off valves 9 are installed at the inlet of the air duct 8 into the pneumatic cylinders 2.

 The device operates as follows. If there is a portion of the open surface of the liquid electrolyte in the projection of the supply of portions of alumina, close the shut-off valve 6 of the pneumatic cylinder 2 of the corresponding punch 1, in the projection of which the open surface of the molten electrolyte. At the same time, the dosing device continues to work according to the given program, and portions of alumina are supplied to the surface of the electrolyte, its dissolution occurs.

 At the same time, the amount of alumina portions can also be changed, namely: in the areas of the open surface of the liquid electrolyte, the supplied alumina is increased in comparison with areas having a cryolite-alumina crust; in the areas of the “board anode” space having a cryolite-alumina crust and an increased volume have fallen, a portion of alumina is reduced in comparison with areas having an open electrolyte surface. Changing the size of a single portion can be realized, for example, by changing the number of times the metering device is activated in one cycle, or by changing the time interval for the metering device to be turned on, programmed from the upper level (WU) by using EMU.

 Example. On a group of industrial electrolyzers of the S-8B type for a current strength of 155 kA, equipped with a known device for the automatic supply of alumina to a point-type melt (APG) with punches equipped with a pneumatic drive, with volumetric batchers, an ASUTP system consisting of NU (ШУЭ-БМ4 cabinet) and VU (IBM PC), the electrolysis process is carried out in an automatic mode of alumina feeding according to a given program. Moreover, in the first group of electrolyzers ("A" 1 3) all available punches and metering devices are cyclically triggered; on the fourth electrolyzer ("B"), shut-off valves 6 are installed at the inlet of the air duct 5 into the pneumatic cylinders 2 of the punches 1; on the fifth and sixth electrolyzers ("C", "D") valves 6 are also installed (according to the drawing) and dosing devices are used to change the size of a single portion of the supplied alumina at each feed point.

 Comparative electrolysis is carried out for three months. In the course of work, the presence of the open surface of the liquid electrolyte in each cell is determined. The presence of an increased volume accrued in the projection of the punch, while the electrolyzers "B", "C", "D" use valves 6 at the entrance to the pneumatic cylinders 2 of the punch 1. In addition, the electrolyzers "C", "D" also apply one-time changes portions of the supplied alumina, depending on the presence of sections of the open surface of the electrolyte and the increased volume of the side accretion.

 The results of comparative tests averaged over 3 months of operation of experimental electrolyzers are shown in the table.

 As follows from the results obtained, in the case of a ban on the operation of the punch in the area with an open electrolyte (electrolyzers "G", "D", "G") there is no adhesion of agglomerate to the punch, and the device failures associated with this also ceased. As a result, the service life of pneumatic cylinders and punches increases, and the grade of aluminum obtained increases.

 An increase in the dosage of portions of alumina in the projection of areas with an open surface of the electrolyte compared with areas having an electrolyte-alumina crust (electrolyzers "D", "G") allows you to actively use these areas with an open surface for dissolving alumina, which naturally have a higher temperature and electrolyte circulation rate.

 Reducing the dosage of portions of alumina in the projection of areas with cryolite-alumina crust and an increased volume accrued in the projection of punches, while increasing the dosage of portions of alumina in areas with an open surface of the electrolyte, can achieve an additional reduction in the frequency of anode effects and slightly increase the productivity of the electrolyzer, reduce the operating voltage , the temperature of the electrolyte and the consumption of aluminum fluoride due to a more correct use of electrolyte zones for dissolving hydrochloric alumina portion. At the same time, a natural increase in the alumina supply cycles per day did not lead to failure of the device components, obviously due to a decrease in the influence of such harmful factors as temperature, electrolyte sticking to the punch. As a result, the need for labor is reduced.

 The absence of alumina deposits on the experimental electrolyzers, the decrease in the yield of coal foam also reduces labor costs, energy consumption and increases the productivity of the electrolyzer ("D", "F").

The data obtained also indicate that the most optimal dose of each portion of alumina is a range of 0.19 0.05 kg or relative to the nominal current strength of 1.22 • 10 ^-3 0.32 • 10 ^-3 kg / kA of this type of electrolyzer.

 The frequency of supply of these portions of alumina, providing the resulting increase in economic effect, was within 20 400 s.

 Thus, the proposed method allows to increase the productivity of the cell, the grade of aluminum, to reduce the consumption of electricity, raw materials and labor.

Claims (4)

 1. A method for automatically feeding an aluminum electrolyzer with alumina, including the periodic supply of dosed portions of alumina to the crust, forcing the crust in local areas in the projection for feeding alumina portions, characterized in that, in areas of the open surface of the liquid electrolyte, alumina portions are fed to the electrolyte surface without forcing the crust.  2. The method according to claim 1, characterized in that in areas of the open surface, the dosage of portions of alumina is increased in comparison with the dosage in areas having cryolite-alumina crust.  3. The method according to claim 1, characterized in that in areas having a cryolite-alumina crust and an increased volume has fallen, the dosage of portions of alumina is reduced in comparison with areas having an open electrolyte surface.  4. The method according to PP.1 to 3, characterized in that portions of alumina are fed to the crust or surface of the electrolyte weighing 0.05 0.09 kg with a frequency of 20 to 400 s.

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