BRPI0611458A2 - anode holding apparatus and method - Google Patents

Abstract

Anode holding apparatus and method An apparatus for holding anodes above a cathode in an electrolysis cell, comprising a superstructure, an anode beam to which a plurality of individual anodes (24) are attached, each of the anodes having a shank. anode beam (26) for attachment to the anode beam by means of a main fastener (54), the anode beam is adjustablely mounted to the superstructure, an auxiliary fastener (56) for each anode rod (26), and at least one electric beam (50) with connectors (52) providing electrical connection between the electric beam (50) and the anode rod (26)

Description

ANODY SUPPORTING DEVICE AND METHOD

Invention field

This invention relates to an apparatus and method for holding anodes in an electrolysis cell producing, for example, aluminum, and especially an apparatus and method for adjusting the position of these anodes in a cell.

Invention History

Alumina electrolysis to produce aluminum through the Hall-Heroult process is well known and involves an electrochemical reaction. This process includes an electrolytic cell comprising an electrolyte cell with a plurality of cathodes and anodes. Aluminum oxide is supplied to a cryolite-based bath in which aluminum oxide is dissolved. The electrolytic process is most efficient at bath temperatures between 9400 ° C and 970 ° C. The anodes form carbonaceous anode blocks and aluminum rods that provide the electromechanical connection to the anode beam from which the anodes are suspended. The anodes are partially submerged in the electrolyte to provide an anode-cathode separation distance by passing an electric current. During the electrolytic process, aluminum is produced in the cathode and forms a layer of molten aluminum above the cathode with the cryolite bath floating over the aluminum bed. For efficient electrolytic cell operation, the anode and cathode spacing must be adjusted and maintained at a predetermined optimal distance or within an optimal range. If the anode-cathode space is too large, this will cause a significant voltage drop between the electrodes resulting in greater unwanted electrolyte energy generation. If the space is too small, the electrolyte process becomes unstable and inefficient.

With conventional carbon anodes, anode blocks are continuously consumed during electrochemical sandblasting producing mainly CO2 gases. As a consequence of continued anode consumption, the anode-cathode space increases over time. In order to maintain the spacing of the gap, the cell voltage is continuously monitored and the position of the anodes is periodically readjusted to maintain optimal anode-cathode space.

Due to continued consumption, the anodes have a limited shelf life of approximately four weeks after which they need to be replaced with new anodes. It would be well known to those skilled in the art that changing more than one of all anodes in an electrolytic cell in a short period of time will lead to serious interference in the chemical and thermal processes. Therefore, it is common practice to change only one anode per day in a given cell so that the anode in that cell is between zero and approximately 28 days old.

In a conventional electrolytic cell design, the movable anode support, called an anode beam, is supported by the superstructure. The anodes are attached directly to this anode beam which provides mechanical support and provides electrical current to the anodes. Conventionally, a single anode fixer is used for mechanical fixation as the anode beam electrical contact with the anode beam. Then, the distance between the anodes and the aluminum layer on top of the method is adjusted by raising and lowering the entire beam of the anodes. Thus, throughout the operating life of the anodes, there is a need to raise and lower the anode beam to keep the anode-cathode space within optimal ranges.

Due to the consumption of the anodes, downward displacement of the anode beam prevails and varies between approximately 15 and 20 mm per day. As a result of downward displacement, the anode beam will reach the lowest possible supersession position in the superstructure after another two weeks and then must be lifted with the aid of an anode auxiliary lifting beam that is temporarily positioned above the cell superstructure. This anode lift beam is equipped with devices that hold the anodes in position, while anode chokers are manually opened by operators to allow the anode beam to move back to its highest position. When the anode beam reaches its highest position, all anode fasteners shall be closed again by the operators.

These clamping devices also exert high lateral pressure on the anode rod to maintain electrical contact between the anode rod and the anode beam while the anode beam is moving up and down along the anode rod. The process of raising the anodes poses a significant safety risk because the pressure exerted on the anode rod may drop, resulting in the loss of electrical contact between the anode rod and the anode beam. In this situation, dangerous electrical arcs develop until the aluminum casting device is disconnected due to the open electrical circuit. In this circumstance, operators performing elevation of the anode beam are at risk of burns. Consequently, an objective of the present invention is to provide a device for automatic anode beam elevation without human interaction that addresses one or more of the problems of existing arrangements.

Summary of the invention

In one aspect of the invention, there are provided:

An apparatus for holding anodes above a cathode in an electrolysis cell, including a superstructure, an anode beam to which a plurality of individual anodes are attached, each of the anodes having a respective anode beam for attachment to the anode beam via a main fixer, anode dithofix being adjustable to the superstructure,

• An auxiliary fastener for each anode rod, and at least one electrical beam supported by the superstructure, electrical dithof beam having connectors providing electrical connection between the electrical beam and the anode rod.

In a recommended embodiment of this aspect of the invention, the auxiliary fasteners are secured in a superstructure relative position.

Unlike all known cell technologies, the anode beam of this invention is merely a mechanical fixation to the anode rod that provides vertical anode displacement to control the anode-cathode distance. The anode beam no longer performs the task of conducting electricity to the anodes. This task is accomplished by at least one electrical beam preferably fixed to the central upper portion of the cell superstructure and a plurality of flexible ones. It is recommended that these flexibles be made up of a set of aluminum sheets welded to the electric beam and secured through de-clamping joints or bolted to the top of the anode rod.

Thus, the task of mechanical fixation and anode height adjustment can be kept separate from the electrical connection to the anode rod. Thus, uninterrupted electrical contact is provided to the electric beam while providing a more secure attachment of the anode rod to the movable anode beam.

In a second aspect, the invention provides an apparatus for adjusting the distance between the anodes and the cathode of the electrolysis cell, including an anode beam to which a plurality of individual anodes are attached via the respective anode rod, the anode rod each of the anodes. being secured in position with respect to the anode beam through a main fastener, an auxiliary fastener for each of the anode rods, and a device for controlling the operation of the main fasteners and assisting in allowing the fasteners to engage and disengage.

The apparatus may also be provided with a superstructure. The auxiliary fastener is preferably attached to the superstructure to support the auxiliary fastener during elevation of the anode beam.

In a recommended embodiment of the first and second aspects of the invention, the engagement and disengaging of the main and auxiliary fasteners is controlled by a process control computer. The flexible electrical disconnection and reconnection required for anode-shifting operation is performed with specialized tools attached to the manipulator cranes. The flexible electrical connection will only be opened to perform anode change at the end of the anode block life.

In this invention, the anode beam lifting operation is no longer performed with an auxiliary lifting beam holding the anodes in position as set forth above.

Both fasteners are used for this operation. In order to raise the anode beam, the process control computer will close the auxiliary fasteners to maintain anode positions while disengaging the main fasteners. When the main fasteners of all cell anodes are in the open position, the anode beam can be raised freely. There is no need to maintain electrical contact between the anode beam and anode rod by applying pressure to the rods, as electrical conduction remains uninterrupted through the continuous connection of flexible rods.

According to a third aspect of the invention, there is provided a method of elevating an anode beam in an electrolysis cell, described above, including the steps of:

• Attachment of the auxiliary fasteners to maintain the position of the anodes with respect to the superstructure.

• disengagement of the main fasteners,

• anode beam shift,

• re-engaging the main fasteners, and • disengaging the auxiliary fasteners.

With this invention, it is possible to perform automated elevation of the anode beam much more frequently (eg every day or two) than with a conventional anode beam arrangement where energy-intensive working beam elevation occurs. every two to three weeks. For this reason, the total travel distance of the anode beam can be significantly reduced.

Description of the drawings

Figure 1 is a cross-sectional view of an electrolysis cell and anode support conventional to the prior art, and Figure 2 is a cross-sectional view of an electrolysis and anode support cell according to one embodiment of the invention.

Detailed description of recommended achievements

The prior art electrolysis cell includes a steel outer shell 12 with a lower refractory lining 14 and refractory sidewall lining 16. The lower refractory lining holds a cathode 18 with steel busbars 20 to conduct electricity to tie bars (not shown) on the outside. of the steel housing 12. An anode assembly is illustrated, comprising an anode block 24 connected to an anode rod 26 through a steel breech 22 and sleeves28. The anode rod 26 is mechanically and electrically connected to an anode beam 30 via a securing device 32 attached to the anode beam. Mechanical drive kits (not shown) are provided to elevate and lower the anode beam to vary the anode-cathode space (or rather, the space between submerged anodes in the electrolyte and the aluminum liquid layer above the cathode). desired distance.

The design of the anode raising and lowering equipment is based on the assumption that all anodes will be consumed at a constant rate and thus generally all anodes in the cell can be raised or lowered concomitantly to maintain space within the optimum range. Within the cell superstructure, various alumina bins 34 are provided to provide alumina to tip feeders (not shown) generally positioned between the pairs of anodes.

These anode beam systems depend on a fastener connection that provides sufficient mechanical pressure to maintain the anode rod in a fixed position relative to the anode beam. This same connection provides the electrical connection between the anode beam and the anode rod. Therefore, this system comprises both the electrical connection function and the mechanical clamping function. In addition, removal and addition of the anodes are accomplished by a crane positioned above the electrolytic cell. Because of the cell superstructure design, the crane must necessarily be much higher in order to pass over the superstructure.

While the details of a conventional electrolysis cell are as illustrated in Figure 1, the embodiment of this invention is illustrated in Figure 2. To make understanding easier, structures in carrying out the invention that are similar to those of a conventional electrolysis cell received identical numbering. The anode detentation structure according to the invention includes the electric beam 50, preferably fixed in position and connected to the anode rod 26 via electrical connectors, termed flexible 52. These flexible 52s maintain the electrical connection to the anode rod while providing the rods the ability to move relative to the electric beam 50. Generally, flexible 52s are formed from a plurality of aluminum sheets in the shape of an aluminum laminar block with the structural laminar extending in the direction of current flow. One end of the hoses is welded to the electric beam 50 while the other end is connected to the anode rod top portion through the pin or clamp junction 60.

The anode support structure comprises the main fastener 54 attached to the vertical displacement anode beam 30 and the auxiliary fastener 56 attached to the base plate of the cell superstructure 58. The anode beam is displaced by a mechanical drive (not illustrated) set. similar to the conventional anode unbundling structure. There is a main fastener 54 and an auxiliary fastener 56 for each of the anode rods 26. The main fastener 54 of all the anodes of a cell is continuously engaged except during the anode beam lifting operation. A control device such as pneumatic cylinders or electric motors is provided to operate the engagement and disengagement actions of the main fasteners 54 and auxiliary fasteners 56.

An alumina bin 62, smaller than the prior art bin, is also provided on the superstructure between the anode beams 30. To raise the anode beam, the auxiliary fixers 56 of all anodes in a given cell are closed by the process control computer. .

Subsequently, the main fasteners 54 are opened so that the mechanical drive assembly can raise the anode beam 30 freely. The anodes are kept in overlap by the auxiliary fasteners 56 and the electrical connection provided by the flexible 52 is uninterrupted. Once the anode beam has reached its upper position, the main chokes 54 are closed. This is followed by the opening or disengagement of the auxiliary fasteners 56. All operation of disengaging and re-engaging the fasteners as well as lifting the anode beam is completely automated and does not require the intervention of any operator.

Claims (11)

Anode holding apparatus for holding anodes above a cathode in an electrolysis cell, characterized by including: • a superstructure, an anode beam to which a plurality of individual anodes are attached, each of the anodes having an anode rod fastening to the beam. anodes through a main fixer, said adjustable beam being mounted to the superstructure, • an auxiliary fixer for each anode rod, and at least one electric beam secure through the superstructure, electric dipstick having connectors providing electrical connection between the electric beam and the rod of anodes. Anode holding apparatus for securing anodes above a cathode in an electrolysis cell according to claim 1, characterized in that the auxiliary fasteners are fixed in a position relative to the superstructure. Anode holding apparatus for securing anodes above a cathode in an electrolysis cell according to claim 1 or 2, characterized in that at least one electrical beam is attached to the central upper part of the cell superstructure and a plurality of flexible. Anode holding apparatus for securing anodes above a cathode in an electrolysis cell according to claim 3, characterized in that the flexibles are made of a multitude of aluminum sheets welded to the electric beam and secured by dowel joints or fastening to the electrode. upper part of the anode stem. 5. Anode holding apparatus for holding anodes above a cathode in an electrolysis cell, characterized in that it includes an anode beam to which a plurality of individual anodes are attached via the respective anode rod, the anode rod of each of the anodes being secured. in position with respect to the anode beam through a main fastener, an auxiliary fastener for each of the anode rods, and a device to control the operation of the main fasteners and assist in allowing the fasteners to engage and disengage. Anode holding apparatus for securing anodes above a cathode in an electrolysis cell according to claim 5, characterized in that it is also provided with a superstructure, the auxiliary fixative being attached to the superstructure to support the auxiliary binder during lifting of the electrode beam. anodes. Anode holding apparatus for securing anodes above a cathode in an electrolysis cell according to claim 5, characterized in that the main and auxiliary fasteners engage and disengage are controlled by a process control computer. Anode holding apparatus for securing anodes above a cathode in an electrolysis cell according to claim 7, characterized in that the process controller only permits main fastener disengagements when the auxiliary fasteners are closed. 9. Anode support method for securing anodes above a cathode in an electrolysis cell, characterized by the steps of: • engaging of the auxiliary fasteners to maintain the position of the anodes with respect to the superstructure, • disengaging the main fasteners, • displacement anode beam, • re-engaging the main fasteners, and • disengaging the auxiliary fasteners. Anode holding method for securing anodes above a cathode in an electrolysis cell according to claim 9, characterized in that the main fasteners are only disengaged when the auxiliary fasteners are engaged. Anode holding method for securing anodes above a cathode in an electrolysis cell according to claim 9, characterized in that the auxiliary fasteners can only be disengaged when the main fasteners are engaged.