US3063931A - Multicell electrolytic furnace, including apparatus for rapid starting thereof - Google Patents

Multicell electrolytic furnace, including apparatus for rapid starting thereof Download PDF

Info

Publication number
US3063931A
US3063931A US847538A US84753859A US3063931A US 3063931 A US3063931 A US 3063931A US 847538 A US847538 A US 847538A US 84753859 A US84753859 A US 84753859A US 3063931 A US3063931 A US 3063931A
Authority
US
United States
Prior art keywords
furnace
layer
cells
layers
bath
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US847538A
Other languages
English (en)
Inventor
Varda Giuseppe De
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Individual
Original Assignee
Individual
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from US711660A external-priority patent/US2959528A/en
Priority to CH5528558A priority Critical patent/CH373902A/de
Application filed by Individual filed Critical Individual
Priority to US847538A priority patent/US3063931A/en
Application granted granted Critical
Publication of US3063931A publication Critical patent/US3063931A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • CCHEMISTRY; METALLURGY
    • C25ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
    • C25CPROCESSES FOR THE ELECTROLYTIC PRODUCTION, RECOVERY OR REFINING OF METALS; APPARATUS THEREFOR
    • C25C3/00Electrolytic production, recovery or refining of metals by electrolysis of melts
    • C25C3/06Electrolytic production, recovery or refining of metals by electrolysis of melts of aluminium
    • C25C3/08Cell construction, e.g. bottoms, walls, cathodes

Definitions

  • This invention relates to an apparatus for the comparatively quick starting of multicell electrolytic furnaces, particularly those employing fused salt baths contained in inclined or vertical individual cells. It especially relates to the starting of a battery, or closed neckless chain or circuit, of closed electrolytic cells employed to produce aluminum by electrolysis of alumina at temperatures, for for example, of from 900 to 1008 C., in a fused fluorinated salt bath, such as cryolite.
  • the principal object of this invention is to provide an apparatus for facilitating the rapid starting of multicell, or necklace, furnaces of the types described in the G. de Varda applications Serial No. 587,985, filed May 29, 195 6, US. Patent 2,952,592, Serial No. 711,577, filed January 28, 1958, and Serial No. 706,077, filed December 30, 1957, US. Patent 2,959,527. or necklace-type electrolytic furnaces, equipped with anodic restoring layers, and with devices for continuously removing the aluminum produced, is possible by adapting known methods. For example, it is possible to introduce, while the furnace is empty, transportable resistors into the individual interelectrodic gaps, as well as into the upper terminal chamber, lower terminal chamber, and alumina feed chamber etc.
  • Heating is effected by passing current through mobile resistors until the interior of the furnace has attained the desired temperature, for example 900 to 950 (3., whereafter the resistors are removed.
  • Fused bath is then fed into all the cells and the anodic restoring layers are set in place, if needed.
  • the electrolysis process is then at once started by applying voltage to the terminals of the furnace.
  • a method of this type presents inconveniences, since the electrolysis process cannot be started until all the cells of the necklace-type circuit have been made ready. These cells may be quite numerous, thirty for example. Making them ready requires time, so that the fluid bath first fed into the cells may tend to solidify. This interrupts the passage of current through the furnace and eventually blocks all the furnace cells. In such case it is hardly possible either to heat the cells to complete bath fiuidification, or to discharge their contents. The only thing that remains to be done is to scrap the cells when the solidification of the bath is terminated.
  • FIG. 1 is a longitudinal section taken at the two planes II of FIG. 2, of a number of adjacent cells of a closed The starting of such multicell,
  • bath circuit electrolysis furnace for aluminum produc tion, with provision for continuous tapping of aluminum, and having fixed and stationary electrodic blocks provided with juxtaposed self-restoring layered anodes, said blocks modified in accordance with the present invention; said section at vertical planes Il is taken across the right structure of HG. 2 on plane I, and then on another plane I in the left structure;
  • FIG. 1A is a fragment of FIG. 1, illustrating alumina coatings between anode layers
  • FIG. 2 is a composite horizontal sectional view taken at diiferent intermediate levels, at AA of FIG. 1;
  • PEG. 3 comprises in part a top View and in part a horizontal section, being taken at BB of FIG. 1;
  • FIG. 4 is a vertical transverse section, at C-C of FIG. 1;
  • FIG. 5 is a'vertical section, at DD of FIG. 4, taken parallel and close to its longitudinal axis;
  • FIG. 6 is a vertical section at line FF of FIG. 1;
  • FIG. 7 is a vertical section at line E-E of FIG. 3;
  • FIG. 8 illustrates the connection of the cells in a necklace, being substantially as described in my prior application Serial No. 587,985, filed May 29, 1956.
  • liquid levels indicated in the five figures are those attained at the termination of the furnace starting operation.
  • the internal cavities or surfaces of the furnace in contact with the bath are, as is known, protected by a refractory lining, for instance of magnesium oxide.
  • a refractory lining for instance of magnesium oxide.
  • the latter may be treated for instance as described in my application Serial No. 705,374, filed December 26, 1957, U.S. 2,952,605, to make them practically impermeable by the bath, maintaining however an electric resistivity higher than that of the fused bath, and, or, by other methods.
  • FIG. 1 a number of upwardly-downwardly extending, inclined bipolar electrodic structures.
  • electrolysis current is introduced through a left end terminal electrode (not shown) constituting an anode electrodic structure.
  • the current passes serially through the intermediate bipolar electrodic structures as indicated by arrow 14- of FIG. 1, and serially through the respective upwardlydownwardly extending intermediate electrolysis gaps, to a right end terminal electrode (not shown) constituting a fixed and stationary cathode electrode.
  • the arrow at it in FIG. 1 indicates the counter-flow of the bath through the conduits ltl passing through the magnesia blocks 4 described below.
  • the stationary and fixed part of the bipolar electrode comprises a number of superposed, or stacked, carbon (preferably graphite) blocks or horizontal layers 2, 3, 23 and 24, surmounted by a magnesium oxide block 4, which in turn is surmounted by heat-insulating members 8. Bridging the top of each electrolysis gap is a supporting piece of magnesium oxide, over which is placed the heat insulative cover plate 9. Refractory, chimneyshaped, conduit structures 6 extend through the outer heat-insulated wall 8!. Conduits 6 are provided with removable cover 5.
  • the anodic surfaces comprise, or are provided with, automatically,
  • anode surface elements or structure which may comprise a single block 1 of prebaked carbonaceous electrode material, or an anodic assembly (not shown) of superposed blocks of the same material.
  • the block 1 continuously descends, as the lower tip, resting uponthe surface of ledge 20, is electrolytically consumed.
  • the block is guided downwardly adjacent to the surface of the stationed parts 2, 3, 23, 24 by the chimney 6.
  • the bottom wall (FIG. 1) and the lateral walls 31 (FIGS. 2, 3, 4) are each provided with an inner lining 22, 39 of magnesium oxide. Ledges 2t) and ribs are part of lining 22. Wall 15 and also lateral walls 31 are composed of or contain heat-insulating material. Any commonly employed heat-insulating porous refractory can be used.
  • a horizontal groove 13 (FIG. 1) is formed in the lower face of each ledge 2i], providing blind, horizontal channels 18. As shown in FIG. 4, the horizontal channels 13, which are normally provided with heat-insulating covers (not shown in FIG. 4), serve to permit introduction of mobile resistors 42. Blind vertical channels 33 (FIGS.
  • each cell may be provided with at least one horizontal and one vertical blind channel.
  • the resistors may be connected with one another. They are connected to a source of power and serve for heating the furnace in the various preparatory procedures, required, for example, for the various stages of impermeabilization with pitch (about 200 C.) and subsequent cooking (about 70% C.) and for the various starting stages (700 C. to 950 C.) of said furnace.
  • the heat generated by the individual, mobile and transportable resistors which are, for example of 3 kw. rating each, is transmitted through the refractory of magnesium oxide. The transmission is fairly good since its coefiicient of heat conductivity is of the order of 0.006 cal/l sec./1 cm./1 cm. 1 C.
  • the two graphite lower layers 23 and 24 of the bipolar electrode have reduced thickness, for example each one is 2 to 4 cm. thick, the upper layers 2 and 3 being, as indicated in FIG. 1, of greater thicknesses.
  • the various layers 23, 24, 2 and 3 of the stationary part of the bipolar electrodes are placed into the individual cells. As shown in FIG. 2, the layers are provided with lateral projections to enable them to slide in the grooves 12. These grooves are formed in the sides of the inner walls 39 and 44 of the furnace, and also in the two small walls 13 (FIG. 2) which divide each bipolar electrode into three substantially equal portions. Wall 13 also divides the active electrodic surfaces into three cathodic zones and into three anodic zones.
  • each layer of electrodic graphite there is spread a veil or coating of alumina to reduce, to a minimum, electric contact with the overlying electrodic layer.
  • face 21 of layer 23 is so coated before placing layer 24 on layer 23.
  • FIG. 1A shows the coatings.
  • the lower face of each layer has a recess 25, and the upper face has a corresponding projection 26, so the superimposed layers fit into each other.
  • These indentations have, among other purposes, the function of securing good alignment of the layers of the graphite electrode, and also the required parallelism with the sliding plane 7 of the anodic restoring assembly 1 overlying the stationary part of the bipolar electrode.
  • the ledges 2i) undeithe electrodes, and also the side walls and the bottom 22 of the lower chambers serving to collect the metal, should be entirely impervious, with respect to the fused metal.
  • Electric resistors are also applied in the upper portion of the alumina feed chambers. These chambers, as well as the terminal chambers, are not shown in the drawings.
  • the furnace After its walls have been impermeabilized to the bath, which contains fused fiuorinated compounds, such as cryolite, the furnace is completed by assembling therein, as already described, the stationary graphite parts of-the bipolar electrodic structures, subdivided into various horizontal layers, and also the terminal electrodes (not shown) provided with metal conductors coming out preferably at the top of the furnace and connected by metal with the furnace terminals.
  • Upper blocks of refractory 4 through which pass the channels 16, are placed thereto.
  • the top insulation 8 and 9 for said blocks and for the opened bath surface is put in place, and also the chimneyshaped members 6.
  • the layers 1 constituting the restoring anodes are introduced into the empty and cold furnace and the correct position of the insulating pad 9 is made certain of, after which the covers 5 above the chimneys are carefully closed.
  • the first stage of starting is now begun by feeding current to the flying or mobile resistors accommodated in the blind-bottom, horizontal channels 18 and the vertical channels 33, in the base and in the side walls respectively of the furnace, as well as the resistors (not shown) in the vertical tapping pockets 35 provided in the inner longitudinal dividing walls 44 of the furnace.
  • the closed furnace Upon heating gradually, the closed furnace is brought up to a temperature of about 700 C. It is convenient to provide an atmosphere of inert gas, for example by means of a stream of nitrogen, in order to avoid oxidation of parts 13, 22, 4, 39, 44.
  • This operation can be carried out in a limited time even if the number of cells is increased.
  • the resistors have been previously removed from the tapping pockets in order to enable the introduction of fused aluminum, it is neither necessary nor convenient to cut off current from the transportable resistors remaining accommodated in the external walls. Having thus placed all the cells of the circuit in those conditions, one may now feed current to the furnace terminals.
  • amperages equal to those of the full potentiality or capacity of the furnace in normal operation, corresponding for instance to 0.5 ampere for one square centimeter of active electrodic surface in a cell innormal operation, are made to pass through the furnace, the power absorbed will be, for example V of that of normal furnace operation.
  • the bath passes rapidly from the high chamber into the first contiguous cell, that is the one which, through conduit 17 (FIG. 5) is in communication with the pocket 35 provided with the overflow mouth 45, and from that one into the second one, and so forth, passing also through the alumina feed chambers to arrive at the last cell, the lowest one of the necklace. It then discharges into the low terminal chamber side with the high one.
  • This operation takes place in a comparatively limited time, for instance in one or two hours, without any need for disconnecting either the main furnace current or the one passing through the removable resistors.
  • the level 16 (FIG. 1) of the metal in the cell lowers, until the bath has completely displaced the metal from the interelectrodic gap. It is convenient, however, that the quantity of aluminum initially added should be such that when the cell fills with bath liquid the level of the metal in the cell should not descend below the level 19 so that hath liquid will not be introduced into the pocket 35 (FIG. 5) which should fill up with molten metal.
  • the beginning of the electrolysis in all the cells of the circuit filled with bath liquid marks the beginning of the third and last stage of the furnace starting operation.
  • This stage comprises starting the device for lifting the bath from the low terminal chamber to the high terminal chamber.
  • This can be done by means of an oscillating ladle as described in application on Serial No. 670,785, filed July 9, 1957, by G. Calabria, US. 2,991,240, or by means of a graphite pump as described in application Serial No. 705,373, filed December 26, 1957, of De Pava, as well as by other known devices.
  • the measuring devices for all of the alumina feeding stations must be started. It is necessary to thereafter adjust and check the delivery of the bath-lifting device. It is also necessary to check each cell with respect to the attaining of the temperature limits employed in normal operation. If provided, the conventional device for discharging the electrolytic gases from the upper chamber should conveniently now be put to operation. Finally, current may be shut off the circuit of the mobile resistors,
  • channels 18 and 33 are termed blind channels because the molten liquids in the furnace have no access thereto. Obviously, the resistor 14 (FIG. 4) may be inserted farther into the channel 18.
  • order of magnitude means differing by a factor of about one tenth.
  • order of magnitude of 700 C. means the range of about 630 C. to 770 C.
  • the term necklace of cells signifies cells arranged to form a complete, closed circuit arranged for cyclic fiow of bath liquid in the circuit, the electric current passing around the necklace serially through the cells', the bath liquid also passing serially, preferably in the opposite direction, while aluminum oxide is fed into the furnace at least at one point in the liquid circuit, and is carried to the cells by the cyclicly flowing bath liquid.
  • the necklace is flattened, the cells being arranged at opposite sides of an internal wall longitudinally dividing the furnace.
  • FIG. 8 illustrates two necklaces of electrolysis cells, each of rectangular form with head ends joining each other, and having independent bath circuits electrically connected in parallel but accommodated within one single rectangular twin furnace.
  • the single-line arrows indicate the current path.
  • the double-lined arrows 2% indicate the direction of the path of main circulation of the electrolysis bath.
  • a lift device (not shown) lifts the bath from the lower level of chamber 330 to the upper level of chamber 320.
  • a metal casing 301 contains a cell housing 31 formed of layers of refractory, comprising thermally and electrically insulating material, and also contains the four branches 5, 5", 6, 6", each branch constituting groups of cells. Each left and right pair of branches forms an independent necklace of cells, both being assembled intoa twin furnace.
  • each necklace has in common the longitudinal intermediate walls 70 and 8i and the two necklaces have in common a transverse intermediate wall 9.
  • insulation is provided by removable covers liiti, corresponding generally to covers 5 of FIG. 1.
  • Each longitudinal branch of the furnace is formed by a certain number of elementary cells of the type shown in FIG. 1.
  • Alumina supply stations and devices are indicated at 130.
  • At 290 are indicated vertical holes for insertion of plugs 300, which are employed to throttle the horizontal passages 10 shown in FIGS. 1 and 6.
  • Aluminum tapping wells or pockets are indicated at 31.0.
  • a multicell quick starting furnace for the electrolytic production of alumina from fused compounds comprising a plurality of upwardly-downwardly extending bipolar electrode structures provided with upwardly-downwardly extending self-restoring anodic surface devices and having a stationary permanent and fixed part of the bipolar electrodes of graphite, characterized in that each graphite electrode is divided into at least two horizontal layers, the height of a lower layer being only a small fraction of the over-all height of the layers and that between said lower layer and the overlying electrodic layer a thin interstice is formed containing a layer of electrically non-conductive material to reduce to a minimum electric contact with the overlying electrodic layer.
  • a multicell quick starting furnace for the electrolytic production of alumina from fused compounds comprising a plurality of upwardly-downwardly extending bipolar electrode structures provided with upwardly-down wardly extending downwardly feeding self-restoring anodic surface devices and having a stationary, permanent and fixed part of the bipolar electrodes of graphite, characterized in that each graphite electrode part is divided into at least two horizontal layers, the height of a lower layer being only a small fraction of the over-all height of the layers and in that said lower layer is separated from the overlying electrodic layer by a thin layer of sub stance which is not electric-conductive, to reduce to a minimum electrical contact with the overlying electrodic layer, the graphite layers being respectively provided with interdi'gitating projections and recesses, to maintain them in a predetermined form of alignment, to provide a flush surface, the self-restoring anodic surface device being located at said surface, said interdigitations constituting a hindrance to passage of bath liquid from cell to cell through the interstices between
  • the thin layer comprising alumina and the thermal expansions and contraetions of the refractory elements contacting the graphite electrodes being accommodated by the interdigitations.

Landscapes

  • Chemical & Material Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Electrochemistry (AREA)
  • Materials Engineering (AREA)
  • Metallurgy (AREA)
  • Organic Chemistry (AREA)
  • Electrolytic Production Of Metals (AREA)
US847538A 1957-01-31 1959-10-20 Multicell electrolytic furnace, including apparatus for rapid starting thereof Expired - Lifetime US3063931A (en)

Priority Applications (2)

Application Number Priority Date Filing Date Title
CH5528558A CH373902A (de) 1957-01-31 1958-01-30 Verfahren zum Anfahren von Mehrzellenöfen für die elektrolytische Aluminiumherstellung und Mehrzellenofen zur Durchführung dieses Verfahrens
US847538A US3063931A (en) 1957-01-31 1959-10-20 Multicell electrolytic furnace, including apparatus for rapid starting thereof

Applications Claiming Priority (3)

Application Number Priority Date Filing Date Title
IT162257 1957-01-31
US711660A US2959528A (en) 1957-01-31 1958-01-28 Method of rapidly starting closed multicell electrolytic furnaces
US847538A US3063931A (en) 1957-01-31 1959-10-20 Multicell electrolytic furnace, including apparatus for rapid starting thereof

Publications (1)

Publication Number Publication Date
US3063931A true US3063931A (en) 1962-11-13

Family

ID=32475046

Family Applications (1)

Application Number Title Priority Date Filing Date
US847538A Expired - Lifetime US3063931A (en) 1957-01-31 1959-10-20 Multicell electrolytic furnace, including apparatus for rapid starting thereof

Country Status (2)

Country Link
US (1) US3063931A (de)
CH (1) CH373902A (de)

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US979497A (en) * 1908-10-27 1910-12-27 Electro Chimie Soc D Means for the electrolytic manufacture of sodium.
DE723448C (de) * 1939-11-09 1942-08-05 Vaw Ver Aluminium Werke Ag Kohlenanode
US2451494A (en) * 1947-01-28 1948-10-19 Reynolds Metals Co Enriching alumina content of cryolite fusions
US2748073A (en) * 1951-12-11 1956-05-29 Nat Lead Co Fused salt electrolytic cell for the production of refractory metals

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US979497A (en) * 1908-10-27 1910-12-27 Electro Chimie Soc D Means for the electrolytic manufacture of sodium.
DE723448C (de) * 1939-11-09 1942-08-05 Vaw Ver Aluminium Werke Ag Kohlenanode
US2451494A (en) * 1947-01-28 1948-10-19 Reynolds Metals Co Enriching alumina content of cryolite fusions
US2748073A (en) * 1951-12-11 1956-05-29 Nat Lead Co Fused salt electrolytic cell for the production of refractory metals

Also Published As

Publication number Publication date
CH373902A (de) 1963-12-15

Similar Documents

Publication Publication Date Title
US4243502A (en) Cathode for a reduction pot for the electrolysis of a molten charge
US3764509A (en) Electrolytic furnaces for the production of aluminium
EP0027016A1 (de) Apparat für die elektrolytische Gewinnung von Magnesiummetall aus seinem Chlorid
NO852120L (no) Karbonholdig anode for aluminiumfremstilling ved elektrolyse.
US2528905A (en) Construction of the lower portion of igneous electrolytic cells
US3063931A (en) Multicell electrolytic furnace, including apparatus for rapid starting thereof
US2959528A (en) Method of rapidly starting closed multicell electrolytic furnaces
RU2245395C2 (ru) Графитовый катод для электролиза алюминия
US3256173A (en) Electrolytic furnace with lined cathode pots for the production of aluminum
US2758964A (en) Continuous electrode and method of making the same
US3029194A (en) Furnace and process for the electrolysis of aluminum
US3871922A (en) Gas diffusion electrode for electrochemical cells
GB1046705A (en) Improvements in or relating to the operation of electrolytic reduction cells for theproduction of aluminium
US2959527A (en) Self-restoring anode in multi-cell furnaces particularly for the electrolytic production of aluminum
US3647673A (en) Stepped bottom for multicell furnace for production of aluminum by electrolysis
US2952592A (en) Multicell closed circuit furnace and fused salt electrolysis process for aluminium production from aluminium oxide
JPS61183488A (ja) 非対称の陰極棒及び断熱材をもつホール・エルー電解槽
US1782616A (en) Electrolytic apparatus for refining aluminum and for like processes
CN110079829B (zh) 一种焦粒封装式焙烧启动方法
AU2019235250B2 (en) Cathode elements for a Hall-Heroult cell for aluminium production and a cell of this type having such elements installed
US2938843A (en) Process for the production of aluminum by fused bath alumina electrolysis and three-layer anode for carrying out said process
US2472612A (en) Electric furnace
NO140645B (no) Ionisasjonskammer, saerlig for ionisasjonsroekmeldere
US3107212A (en) Method and apparatus for baking and preheating bottoms of electrolytic cells by meansof alternating or direct current
US3382166A (en) Method and apparatus for starting up multicell electrolytic furnaces for aluminum production