NO310731B1 - Method and apparatus for feeding an electrolysis cell - Google Patents

Description

The present invention relates to a method and a device for spot feeding an electrolysis cell, preferably an electrolysis cell for the production of aluminum according to the Hall-Héroult process.

Point feeders for dosing aluminum oxide or alumina, fluoride and other materials to be fed into an electrolysis cell for the production of aluminum are today well-established technology. In combination with a crust breaker or a skewer, a point feeder can add the desired amount of additive material to a pre-defined point in the cell with reasonably good precision. A cell can have several point feeders, such as 2 - 6 feeders. Consideration of acquisition and maintenance costs means that feeding is carried out at a limited number of points. Over time, feeding materials to the cell via a few individual points could lead to a build-up of sludge (excess material) under and near the feed points. In electrolysis cells with prebaked anodes in two rows, it is common to feed along a center line located between the anode rows. Over time, a ridge of sludge can build up on the bottom of the cell, oriented in the cell's longitudinal direction. Such a more or less continuous elevation of relatively large amounts of sludge could affect the cell's operating conditions and result in unstable operation.

DE 3047533 relates to a beam for mounting above an electrolysis cell, where the beam can support a mobile point feeder unit. A disadvantage of this solution is that it includes a number of moving parts beyond the point feeder unit itself, which can lead to extensive maintenance and operational disruptions due to high temperatures and a dusty and corrosive environment.

NO 128226 shows a dosing system for supplying aluminum oxide to an electrolytic cell, where a reservoir and a dosing device are arranged next to the cell. Furthermore, the plant comprises a supply line which is internally equipped with fluidizing means so that aluminum oxide can flow as a fluid along the supply line. In the side walls of the supply line, there are openings with adjustable, perforated plates arranged for the introduction of aluminum oxide into the cell in approximately equal portions. According to Figure 1, the feeding takes place in a central area between two longitudinal rows of anodes.

NO 154525 shows a solution for feeding aluminum oxide from a store to an electrolysis cell. The supply is provided on both long sides with a dosing device that allows aluminum oxide to be added in portions through the downpipe into the bath.

The above-mentioned solutions indicate nothing in the direction of feeding in points located as described in the present solution.

With the present invention, the starting point is that the feeding should take place in areas so that the operation of the cell is improved, while at the same time the investment and maintenance costs do not become prohibitively high. With the present invention, smaller doses can be fed at several points. In this way, the oxide is mainly dissolved directly in the cryolite melt and sludge does not build up on the cathode. The operation of the cell becomes more stable, which means less work for the cell attendants and metal tappers. Another advantage is that the feed holes can be kept open without the spigots being operated each time oxide feeding is carried out, partly due to less dosage in each hole, partly because it is fed in areas where the outflow of anode gas is prominent, which results in savings regarding wear and reduced energy requirements (compressed air ) to operate the woodpeckers. Furthermore, it will be possible to obtain improvements regarding the cell's current yield, due to more stable and optimal operation.

These and other advantages can be achieved with the invention as defined in claims 1 and 2.

In what follows, the invention will be described in more detail with the help of examples and figures where: Fig. 1 shows, seen from the side, a point feeder in accordance with the present

invention,

Fig. 2 shows, seen from the front, a point feeder in accordance with the present one

invention,

Fig. 3 shows, seen from the front, a crust breaker for use in connection with a

point feeder in accordance with the present invention,

Fig. 4 shows, seen from above, a first schematic representation of the distribution of

feed points in an electrolysis cell,

Fig. 5 shows, seen from above, a second schematic representation of the distribution of feed points in an electrolysis cell.

Figure 1 shows a point feeder 1 in accordance with the invention from the side. The feeder comprises an oxide silo 2 and a fluoride silo 3 attached to the cell's upper frame structure 4, 5. The silos shown are funnel-shaped and taper down towards an outlet 6, 7. At the outlet, in this design, dosing devices are arranged which are made up of tray feeders 8 ,9, but also other types of feeders can be used such as fluidized feeders or screw feeders. In this example, the oxide feeder 8 is equipped with two outlets 10, 11, which feed oxide directly into the bath between anodes 12, 13. The anodes are located partially down in the bath crust (not shown) and a double spit 14 arranged for vertical movement can be pushed through the crust for to maintain holes for feeding (feeding holes) in the crust. The fluoride silo 3 as shown in the figure is equipped with one outlet opening 18, where fluoride can be fed through one of the aforementioned feed holes. Figure 2 shows, seen from the front, a point feeder in accordance with the invention, where an oxide silo 20 with a funnel-shaped lower part 21 is equipped with an outlet nozzle 22. The outlet nozzle 22 is assigned to a horizontally located distribution pipe 23 which is assigned to outlet pipes 24, 25 with associated outlet opening -nings 26, 27. It should be understood that the distributor pipe 23 can be equipped with more than two outlet pipes for distributing material to several points (not shown). In the embodiment as shown in Figure 2, a motor-driven screw feeder with motor 28 is also shown which drives the end of the feed screw 30 via transmission element 29. Screw feeders are well known to those skilled in the art, so this is not described in more detail here. Figure 3 shows a woodpecker device 40 which consists of a multiple woodpecker consisting in this embodiment of two woodpecker 41, 42 (double woodpecker) assigned to a yoke 43 which is connected to an actuator 44 or cylinder via a rod 45. It should be understood that additional woodpecker can be assigned to the yoke for maintaining several feeding holes in the bath crust. The rod 45 can be encapsulated by a housing 46 for protection against corrosion and dust, as well as lateral forces in the piston rod 45. The actuator can be air-driven, but other types of actuators can also be relevant in such an application, e.g. hydraulic, mechanical or electrical. The upper end of the actuator can be attached to a silo 47. In Figure 1, a corresponding spit device is shown from the side with actuator 15, rod 16, and housing 17.

Figure 4 shows a schematic distribution of feed points in an electrolysis cell 60, seen from above. In this embodiment, twenty anodes 63 are arranged in two rows 61, 62. Furthermore, the anodes within each row are arranged in three groups where a slot is allocated between each group, two slots in total. In accordance with the invention, feeding holes 64, 65, 66, 67 are arranged in the slots. The feeding takes place in pairs by two centrally placed feeders or groups of feeders 68, 69 for, for example, oxide, fluoride or soda, and is distributed to the holes 64, 65 and 66, 67 respectively.

Figure 5 schematically shows a distribution of feed points in an electrolysis cell 80, seen from above. In this embodiment, the cell is equipped with thirty-two anodes 83 distributed over two rows 81, 82. In each row, the anodes are divided into four groups so that a slot is formed between each group, three slots in total. In these slots, feed holes 84, 85, 86, 87, 88, 89 are placed, for the supply of materials for operating the cell, such as oxide, fluoride, soda etc. In the same way as in the previous example, the feed holes (84, 85 ), (86, 87), as well as (88, 89) are served in pairs by three feeders or three groups of feeders (not shown).

It should be understood that the described technology can also have other applications where it is important to obtain a good dispersion of the dosed material. Thus, the invention can be used within other electrolysis processes, such as the production of aluminum by the Søderberg process.

Claims (6)

1. Method for point feeding of materials such as aluminum oxide, cryolite, etc., to an electrolysis cell (60), preferably an electrolysis cell for the production of aluminum according to the Hall-Héroult process, where material placed in a store, for example a silo (2), is divided into two or several points (64,65) in the bath crust of the cell, characterized by that the points to which material is supplied are located in gaps formed between groups of anodes (63). 2. Device for spot feeding of materials, such as aluminum oxide, cryolite, etc., to an electrolysis cell (60), preferably an electrolysis cell for the production of aluminum in accordance with the Hall-Héroult process where anodes (63) are arranged in rows, and where the device further comprises a supply (2) for material, a dosing device (8) with an outlet, as well as a spit (14) or crust breaker for maintaining feeding holes in the bath crust of the cell, the dosing device further comprising a distributor pipe (23) with at least two outlets (10, 11) for distribution of material to two or more points (64,65) in the cell (60), characterized in that the anodes are further arranged in groups within each row, and where the distribution pipe (23) is placed in a transverse direction in relation to the anode rows, in that the outlets (10,11) project into each row and are further placed in gaps formed between anodes or groups of these. 3. Device in accordance with claim 2, characterized by that the spike consists of a multiple spike (40) with two or more spikes (41,42) interconnected by a yoke (43) which is moved by an actuator (44). 4. Device in accordance with requirements 2-3, characterized by that the dosing device consists of a tray feeder (8). 5. Device in accordance with requirements 2-3, characterized by that the dosing device consists of a fluidized feeder. 6. Device in accordance with claims 2-3, characterized in that the dosing device consists of a screw feeder.