RU2018117703A

RU2018117703A - A SERIES OF ELECTROLYZERS FOR PRODUCING ALUMINUM CONTAINING MEANS FOR BALANCING MAGNETIC FIELDS AT THE END OF A SERIES

Info

Publication number: RU2018117703A
Application number: RU2018117703A
Authority: RU
Inventors: Бенуа Барде; Оливье МАРТЭН
Original assignee: Рио Тинто Алкан Интернэшнл Лимитед
Priority date: 2015-10-15
Filing date: 2016-10-03
Publication date: 2019-11-15
Also published as: FR3042509A1; CA3000482C; CN108368624A; ZA201801921B; EP3362590B1; RU2018117703A3; CA3000482A1; RU2722026C2; WO2017064547A1; AU2016339054A1; EP3362590A4; FR3042509B1; EP3362590A1; AU2016339054B2; CN108368624B

Claims

1. A series (1) of electrolytic cells (100), designed to produce aluminum by melt electrolysis according to the Hall-Hero method, containing:

- at least one first and one second rectilinear and parallel to each other rows (F, F ') of electrolytic cells, electrically connected in series,

- a connecting conductor (20) between the first end electrolyzer (100 ') of the first row and the first end electrolyzer (100') corresponding to the second row,

and characterized in that the series comprises at least one circuit (21) for magnetic balancing of the end row electrolytic cells, comprising a first electrical conductor (22) of magnetic balancing of the end row electrolytic cells, extending along the first row of electrolytic cells just opposite the end portion (P) of the first row of electrolytic cells.

2. A series of electrolyzers according to claim 1, in which the circuit (21) for magnetic balancing of the end electrolytic cells of the series includes a second electrical conductor (23, 23 ', 23' ') parallel to the first electric conductor 22 of magnetic balancing of the terminal electrolyzers of the series.

3. A series of electrolyzers according to claim 2, in which the second electrical conductor (23 ') extends along the first row (F, F') of electrolyzers just opposite the end portion (P) of the first row of electrolyzers, the first and second electrical conductors (22, 23 ) extend along opposite sides of the first row of cells.

4. A series of electrolyzers according to claim 2, in which the second electrical conductor (23) extends from the same side of the first row (F, F ') of the electrolyzers as the first electrical conductor (22), the distance between the first electrical conductor and the first row electrolyzers is less than the distance between the second electrical conductor and the first row of electrolyzers.

5. A series of electrolyzers according to claim 4, in which the second electrical conductor (23 ″) extends along the second row (F, F ′) of electrolyzers just opposite the end portion (P ′) of the second row of electrolyzers.

6. A series of electrolytic cells according to any one of the preceding paragraphs, in which the circuit (21) for magnetic balancing of the terminal row electrolytic cells includes two ends that are connected to a power substation (30).

7. A series of electrolyzers according to any one of paragraphs. 1-5, in which the magnetic balance circuit (21) of the terminal row electrolysers includes two ends that are connected to conductors electrically connecting the electrolysers to each other.

8. A series of electrolyzers according to any one of paragraphs. 1-5, comprising a correction circuit (26) comprising at least one first correction conductor (27) extending along the first row (F, F ′), a second correction conductor (27) extending along the second row (F, F ′ ), and at least one connecting correction conductor (28) between the first and second correction conductors (27), and in which the magnetic balance circuit (21) of the terminal row electrolytic cells includes two ends that are connected to the correction circuit (26).

9. A series of electrolyzers according to claim 8, in which the circuit (21) for magnetic balancing of the terminal row electrolysers is connected in series between two sections of the correction circuit (26).

10. A series of electrolyzers according to any one of paragraphs. 8 and 9, in which the first correction conductor (27) extends along the first row (F, F ') from the side of the second row, and the second correction conductor (27) extends along the second row (F, F') from the side of the first row of electrolyzers.

11. A series of electrolyzers according to any one of paragraphs. 8-10, in which the first conductor (22) and the second conductor (23) of the magnetic balancing circuit (21) connected to the correction circuit (26) are located outside of two rows (F, F ') of electrolyzers.

12. A series of electrolytic cells according to any one of the preceding claims, in which the connecting conductor (20) includes a magnetic balancing conductor (40) of the first end electrolyser (100 ') extending along the first end electrolyzer perpendicular to the longitudinal axis of the row (F, F') of electrolyzers , and in which the first electrical conductor (22) does not extend along the first end cell.

13. A series of electrolyzers according to claim 12, when it depends on claim 11, in which the circuit (21) for magnetic balancing of the end electrolyzers of the series includes a transverse conductor (24) that electrically connects the correction circuit (26) to the first electric conductor (22 ), the transverse conductor extending beneath a series of (F, F ') electrolyzers.

14. A series of electrolytic cells according to any one of the preceding paragraphs, in which the magnetic equilibrium circuit (21) of the end row electrolytic cells forms a plurality of turns, and the first magnetic balancing electrical conductor (22) is formed by a plurality of branches (29) of a coil extending side by side along the first row ( F, F ') of electrolyzers just opposite the end portion P of the first row of electrolyzers.

15. A series of electrolysis according to any one of the preceding paragraphs, in which the end portion (P) of the first row (F, F ') of the cells contains from 3 to 10 cells, and preferably from 6 to 8 cells.

16. The method of application of the series (1) of electrolytic cells (100) according to any one of the preceding paragraphs, in which the electrolysis current (I ₀ ) is passed through the rows (F, F ') of the electrolytic cells and the connecting conductor (20) and in which through the first electrical conductor ( 22) magnetic balancing pass electric current balancing (I ₁ ):

- flowing in the same direction as the electrolysis current (I ₀ ), flowing in the first row (F, F ') of the electrolysers, if the first electric conductor (22) of magnetic balancing is located along the first row of electrolyzers from the side of the second row (F, F ') electrolyzers;

- flowing in the opposite direction with respect to the electrolysis current (I ₀ ) flowing in the first row (F, F ') of the electrolytic cells, if the first electrical conductor (22) of magnetic balancing is located along the first row of electrolytic cells from the side opposite to the second row (F, F ') electrolyzers.

17. A method of using a series of electrolyzers according to claim 16, in which series (1) comprises a second magnetic equilibrium (23, 23 ′, 23 ″) electrical equilibrium conductor and in which the same equilibration electric current is passed through this second magnetic equilibrium conductor ( I ₁ ), but flowing in the direction opposite to the balancing electric current (I ₁ ) flowing along the first magnetic balancing electric conductor (22).