 |
52 (2) (2000), pp. 22-28. |
|---|
|
52 (2) (2000), pp. 22-28. |
|---|
|
TABLE OF CONTENTS |
|---|
|
|
 |
|
Figure 1. Pechiney AP-30 300 kA "super pot" PB cell technology |
There are currently more than 50 different types of PB cell technologies being used in the aluminum industry. This article reviews the current status of prebake cell technology worldwide with a look at some of the leading aluminum producers and their technologies. The nomenclature for prebake cells is also discussed.
Aluminum companies are operating more than 50 different types of prebake (PB) cell technologies at smelters worldwide. Seventeen additional types of prebake cells are currently operating in Russia and China.
Over the years, significant improvements and changes in the operation of PB cells have occurred. Potline amperages have increased 500% from the 1940 vintage 50 kA cells to the current 300 kA super pots (Figure 1). Correspondingly, the total carbon anode area in PB cells has increased with the use of larger anodes from 5 m2 to 38 m2. The operational performance of modern PB cells has dramatically improved to 95–96% current efficiency, 13.5 DC kWh/kg and 1.1 work hours per tonne aluminum. Other significant changes in the design and operation of PB cells include
Improved busbar designs (including magnetic compensation of older PB cells) to reduce magnetohydrodynamic effects
Alcan Aluminium developed three versions of end-to-end, side-work PB cell technologies that are still in use at various smelters and one side-by-side, point-feed PB cell that is no longer in operation (Table I).
There are five potlines of 70 kA end-to-end, side-work PB cells
at the Arvida plant (situated in Jonquière, formerly known as Arvida). The first
generation of cells was started in 1940–1941 at 45 kA and were upgraded to 65
kA from 1963 to 1969 and then to 70 kA.
Two potlines of 160 kA end-to-end, side-work PB cells are used at Lynemouth
(line one started up in 1972, line two in 1973). Original amperage was 140 kA).
Both have been converted from side-work to point-feed technology.
Three potlines of end-to-end, side-work PB cells are operational at Kurri Kurri
(line one started up in 1969 at 148 kA, line two in 1979 at 160 kA, and line
three in 1985 at 175 kA). Potlines two and three at Kurri Kurri have been converted
from side-work to center-work and point-feed technology.
Alcan developed and operated
five experimental side-by-side, point-feed PB cells at Jonquière from 1981–1992.
The busbar design had four side risers, four cathode busbars below the cells,
and two around the ends. The first generation of cells, Apex and A-275, operated
at 280 kA. The last generation of cells, A-310, operated at 310 kA. Most of
these had individual anode drives and computer control adapted to this feature.
|
Table I. Global
Prebake Cell Technology
|
||||||
|
Company/Cell
|
UPBN Name
|
kA
|
Riser Design
|
Number of
Alumina Feed |
Anodes
|
Smelters
|
|
Arvida Prebake
|
AC-7-EE
|
70
|
End-to-end |
18
|
Jonquière
|
|
|
LynemouthA
|
AC-16-EE-M1
|
160
|
End-to-end
|
22
|
Lynemouth
|
|
|
KK-1
and KK-2A |
AC-16-EE-M2
|
160
|
End-to-end
|
22
|
Kurri Kurri
|
|
|
KK-3A
|
AC-17-EE-M3
|
175
|
End-to-end
|
22
|
Kurri Kurri
|
|
|
Apex, A-275A
and A-310 |
AC-28
and AC-31 |
280
& 310 |
Side-by-side
four side risers |
24
|
Arvida R&D CenterB
|
|
|
N-40 (Niagara)
|
AA-4
|
40-80
|
Side-by-side
|
24
|
Mead, Troutdale
|
|
|
AA-4-SE
|
End riser and
Side risers |
24 and 26
|
Renukoot,
Vancouver 28 |
|||
|
P-88
|
AA-10-SE3
|
100
|
Side-by-side
end risers |
24
|
Warrick
|
|
|
T-51
|
AA-10-SE1
|
100
|
Side-by-side
end risers |
20
|
Rockdale,
Wenatchee |
|
|
P-75
|
AA-10-SE2
|
100
|
Side-by-side
end risers |
20
|
MassenaB
|
|
|
P-100
|
AA-10
|
125-130
|
Side-by-side
two side risers |
26
|
Rockdale, Warrick,
Wenatchee |
|
|
P-155
|
AA-16
|
155-180
|
Side-by-side
two side risers |
24
|
Badin, Grande Baie,
Laterrière, Pt. Henry, Sebree |
|
|
A-697
|
AA-18
|
180
|
Side-by-side
two side risers |
24
|
Mt. Holly, New Madrid,
São Luis |
|
|
P-225
|
AA-23
|
225
|
Side-by-side
four side risers |
32
|
Massena,
Tennessee |
|
|
A-817
|
AA-30
|
275-300
|
Side-by-side
five side risers |
40
|
Portland
|
|
|
EPT-10
|
AS-8-SE
|
80-130
|
Side-by-side
end risers |
22
|
||
|
EPT-10
|
AS-8-EE-M1
|
80-130
|
End-to-end
|
24
|
Steg, Delfzijl,
Straumsvík (Potroom 1 and 2) |
|
|
EPT-10C
|
AS-8-EE-M2
|
80-150
|
End-to-end
|
24
|
Husnes
|
|
|
EPT-10C
|
AS-8-EE-M3
|
80-130
|
End-to-end
|
24
|
Straumsvík
(Potroom3) |
|
|
EPT-14
|
AS-14-EE-M1
|
140-145
|
End-to-end
|
26
|
||
|
EPT-14C
|
AS-14-EE-M2
|
140-170
|
End-to-end
|
26
|
Essen
(Potroom 3) |
|
|
EPT-14
|
AS-15-EE
|
145-170
|
End-to-end
|
26
|
Hillside
|
|
|
EPT-18
|
AS-18
|
180-190
|
Side-by-side
side risers |
32
|
RheinfeldenD
|
|
|
Comalco
and Dubal
|
||||||
|
CD-200
|
CD-20
|
190-206
|
Side-by-side
side risers |
20
|
Dubai, Tiwai Point
|
|
|
HAL-150C
|
HAL-15-EE-M
|
160-175
|
End-to-end
|
20,22
|
Årdal,
Sunndalsøra |
|
|
HAL-230
|
HAS-23
|
230
|
Side-by-side
four side risers |
26, 30
|
Høyanger,
Venalum (line 5), Ziar |
|
|
HAL-250
|
HAL-25
|
250
|
Side-by-side
four side risers |
30
|
Årdal
|
|
|
P-93
|
KA-6-EE
|
60
|
End-to-end
|
6
|
Tacoma,
Nadvoitsy |
|
|
P-57E
|
KA-9-SE
|
93
|
Side-by-side
end risers |
20
|
Bell Bay,
Ravenswood |
|
|
P-69
|
KA-14-SE
|
140-175
|
Side-by-side
end risers |
18
|
Hollyhead, Dubai,
Tema, Hawsville, New Madrid, Tiawai Point, Voerde |
|
|
P-86
|
KA-15
|
150
|
Side-by-side
side risers |
16
|
Sundsvall
|
|
|
P-80
|
KA-18
|
180-190
|
Side-by-side
side risers |
16
|
||
|
AP-7
|
AP-70-SE
|
70
|
Side-by-side
end risers |
12
|
St. Nicolas
|
|
|
AP-9
|
AP-9-SE
|
90
|
Side-by-side
end risers |
16
|
||
|
AP-LN
|
AP-9-EM
|
90
|
End-to-end
end riser and two side risers |
20
|
Lannemenzan
|
|
|
AP-CM
|
AP-13-EEM
|
125
|
End-to-end
end riser and two side riser |
24
|
Edéa
|
|
|
AP-13
|
AP-13-SE
|
130
|
Side-by-side
end risers |
18
|
Belem, Frederick,
Ferndale, Vlissingen |
|
|
AP-14
|
AP-14-SE
|
140
|
Side-by-side
end risers |
20
|
Mostar, San Ciprian
|
|
|
AP-18
|
AP-18-16
|
180
|
Side-by-side
four side risers |
16
|
Baie Comeau, Bécancour,
Ft. William, Karmøy, Kidricevo, Orissa |
|
|
AP-18-18
|
18 (Aluar)
smaller anodes |
St. Jean-de-Maurienne
(F Line), Tomago, Puerto Madrym |
||||
|
AP-30
|
AP-30-20
|
300
|
Side-by-side
five side risers |
20 (double)
|
Bahrain, Dunkirk,
Sept-Iles, Hillside |
|
|
40 (single)
|
Boyne, Deschambault,
St. Jean-de-Maurinne (G Line) |
|||||
|
P-6G
|
RY-8-SE
|
75
|
Side-by-side
end risers |
28
|
Alcasa, Arak,
Troutdale |
|
|
Invergordan
|
RY-14-SE
|
130
|
Side-by-side
end risers |
18
|
InvergordonH
|
|
|
P-19G
|
RY-16-SE
|
145-165
|
Side-by-side
end risers |
18
|
Hamburg, Venalum,
Alcasa, Santa Cruz |
|
|
P-19SG
|
RY-16
|
160-170
|
Side-by-side
side risers |
18
|
Alcasa, Hamburg
|
|
|
P-20SG
|
RY-17
|
170
|
Side-by-side
side risers |
18
|
Alcasa, Ikot Abasi
|
|
|
P-23SG
|
RY-18
|
180
|
Side-by-side
side risers |
18
|
Alcasa
|
|
|
Erftwerk
|
VAW-11-EE
|
110-126
|
End-to-end
|
Continuous
|
Stade
|
|
|
CA-120
|
VAW-12-EE
|
120
|
End-to-end
|
14
|
Danjiangkou
|
|
|
CA-165C
|
VAW-17-EE-M
|
165-170
|
End-to-end
|
20
|
Bayside, Rheinwerk
|
|
|
CA-180
|
VAW-18
|
180
|
Side-by-side
side risers |
20
|
Grundartangi
|
|
|
CA-240
|
VAW-24
|
240
|
Side-by-side
side risers |
24
|
TögingB
|
|
|
CA-300
|
VAW-30
|
300
|
Side-by-side
side risers |
32
|
SayanskB
|
|
|
Montecatini
|
||||||
|
P-115
|
MS-12-EE
|
115-125
|
End-to-end
|
16
|
Bahrain
|
|
|
P-155
|
MS-16-EE
|
155-165
|
End-to-end
|
16
|
Fusina, Puerto Madryn,
Porto Vesme |
|
|
Elkem
|
||||||
|
P-155
|
EK-16
|
155
|
End-to-end
|
18
|
Mosjøen
|
|
|
Sumitomo
|
||||||
|
S-170C
|
SM-17-SE
|
185-00
|
Side-by-side
end risers |
18
|
Boyne Island,
Kula Tanjung |
|
|
P-200C
|
EG-20-EE-M
|
200
|
End-to-end
|
24
|
Nag Hammadi
|
|
|
Venalum
|
||||||
|
V-350
|
VN-35
|
320
|
Side-by-side
four side risers |
36
|
Puerto Ordaz
|
|
|
Russia
|
||||||
|
C-50
|
RU-5-EE
|
50
|
End-to-end
|
26
|
Volkhov
|
|
|
C-125MC
|
RU-13-EE-M
|
125
|
End-to-end
|
14
|
Krasnoyarsk (Line 8)
|
|
|
C-160C
|
RU-16-EE
|
155-165
|
End-to-end
|
22
|
Krasnoyarsk (Line 7),
Tadzhik, Kamensk-Uralsky |
|
|
C-175M2C
|
RU-18-M2
|
175
|
End-to-end
|
24
|
Sayansk, Tadzhik
|
|
|
C-190C
|
RU-19-EE
|
180
|
End-to-end
|
26
|
Sayansk
|
|
|
C-255
|
RU-26
|
255
|
Side-to-side
side risers |
36
|
Tajik, Sayansk,
Volgograd (four pots) |
|
|
C-255M1
|
RU-26-M1
|
|||||
|
C-255M2
|
RU-26-M2
|
|||||
|
C-300
|
RU-30
|
300
|
Side-by-side
four side risers |
32
|
SayanskB
|
|
|
China
|
||||||
|
P-60
|
CH-6-EE
|
60-75
|
End-to-end
|
10-12
|
||
|
P-75
|
CH-8
|
75
|
Side-by-side
one qt. riser |
10
|
Zhengzhoou
|
|
|
P-115
|
CH-12-EE
|
115
|
End-to-end
|
14
|
DanjiangJ
|
|
|
P-140
|
CH-14-SE
|
135-140
|
Side-by-side
end risers |
20
|
Baotou, Fushun,
Qinyang |
|
|
P-155
|
CH-15-SE
|
150
|
Side-by-side
end risers |
26
|
BaiyinK
|
|
|
P-160
|
CH-16-SE-M
|
160
|
Side-by-side
end risers |
24
|
GuizhouL
|
|
|
P-160
|
CH-16
|
160-180
|
Side-by-side
side risers |
24
|
Pingguo, Qinghai,M
Xinan |
|
|
P-200
|
CH-20
|
185-200
|
Side-by-side
side risers |
28
|
Guizhou,
Kunming |
|
|
P-280
|
CH-28
|
280
|
Side-by-side
side risers |
40
|
Qingyang
|
|
|
P-320
|
CH-32
|
320
|
Side-by-side
side six risers |
48 (20)
|
Pingguo
|
|
|
SW--side work, CW--center
work, PF--point feed. |
||||||
Alcoa
has developed nine different types of PB cell technologies with increasing amperage
that are currently used in aluminum smelters: side-by-side, end-riser PB cells
N-40, T-51, P-75, and P-88 and side-by-side, side-riser PB cells P-100, P-155,
A-697, P-225, and A-817.
In the 1940s, Alcoa
built seven aluminum smelters for the U.S. government using the Alcoa N-40 (Niagara)
50 kA end-riser, center-work PB cell technology, reported to have first been
developed at the Niagara Falls plant. The smelters at Brooklyn, New York; Massena,
New York; and Riverside, California, were shut down. Other aluminum companies
eventually acquired Mead (Kaiser),
Jones Mills and Troutdale (Reynolds),
and Vancouver (Vanalco). All but Jones Mills continue to operate today with
upgraded, modernized versions of the original Alcoa
PB technology. Similar Mead-type PB technology was used by Hindalco to build
potlines at Renukoot, India, in 1974, making significant retrofit modernization
improvements in the original PB cell technology.
In the 1950s, Alcoa
built potlines of the T-51 end-riser design at Rockdale and Wenatchee. An enlarged
version, the P-75, was installed at Massena (it has since been decommissioned)
and another version, the P-88, was installed at Warrick. In the early 1960s,
the first quarter-riser design, the P-100, was installed in potlines at Rockdale,
Wenatchee, and Warrick.
 |
|
Figure 2. Alcoa P-155 PB cells at Latterrière, Canada. |
Alusuisse Aluminium
has developed eight types of PB cell technologies; six are still in operation
at aluminum smelters. End-to-end PB cells include three variations of EPT-10
and three variations of EPT-14. Side-riser PB cells are EPT-10 and EPT-18. The
EPT prefix for Alusuisse PB cells stands for elektrolysezelle mit vorgebrannten
anoden (electrolysis pot with PB anodes), prozessgesteuerter (computer control),
and tonerdezusatz (alumina feed).
 |
|
Figure 3. Alusuisse EPT-10 end-to-end PB cells at Straumsvik, Iceland. |
 |
|
Figure 4. A Comalco-Dubal CD-200 PB cell at Tiwai Point, New Zealand. |
The CD-200 is one of the most recently developed PB cell technologies
in the aluminum industry. Comalco
and Dubal jointly developed the CD-200 200 kA side-riser, point-feed PB cell
with 20 anodes. Dubal now refers to its cell as the CD-20 (20 anodes), as their
cells are operated at an amperage higher than 200 kA. Two potlines (485 cells)
of the CD-200 cells are in operation at Dubai, and a short potline (48 cells)
of CD-200 cells is in operation at Tiwai Point (Figure
4). A higher amperage PB cell is being developed and evaluated in the developmental
potroom at Dubai.
Dubal has made significant retrofit upgrades to the original 499 Kaiser P-69
cells that were initially designed to operate at 140 kA (150 kA maximum). The
cell is now referred to as D-18 (18 anodes) PB cells operate at approximately
180 kA. A few D-18 cells are in operation at Almahdi.
 |
|
Figure 5. A Hydro Aluminium HAL-230 kA PB cell at Ziar, Slovalco. |
Hydro Aluminium
has developed two types of PB cell technologies: end-to-end PB cell HAL-150
and side-riser PB cell HAL-230.
The 150 kA end-to-end (originally side-work) PB cells at Årdal and Sunndalsøra
have been converted to point feeding. The busbar system has been retrofitted
with compensating bus to reduce the high Bz
fields associated with the closeness of the adjacent row of pots in the same
potroom. Four 250 kA cells are in operation in Årdal and are a further development
of the HAL-2130 kA cells. Hydro
Aluminium developed the HAL-230 230 kA four side-riser, point-feed PB cell
at Høyanger, and built a potline at the aluminum smelters at Puerto Ordaz (Venalum)
in 1988 and Ziar (Slovalco) in 1995 (Figure
5).
Kaiser
Aluminum developed five different types of PB cells: side-by-side, end-riser
PB cells P-57, P-69, and P-90 and side-by-side, side-riser PB cells P-80 and
P-86. Kaiser
named their PB cells for the year in which they were developed: P-57 (1957),
P-69 (1969), P-80 (1980), P-86 (1986), and P-90 (1990).
Four cells are still in operation. The Kaiser P-57 90 kA PB cell is operated
at both Ravenswood (Century) and Bell Bay (Comalco)
smelters. The Kaiser P-69 150 kA end-riser, center-work PB cell was one of the
first international PB cells, used in seven aluminum smelters at Hollyhead (Anglesey),
Dubai (Dubal), Voerde (Hoogovens), Hawesville (National Southwire), New Madrid
(Noranda), Tiwai Point
(Comalco), and Tema
(Valco). Many smelters have converted from center work to a modified point feeder.
A potline of 60 kA Söderberg cells at Sundsvall (Kubal, formerly Gränges), was
converted in 1987 to 56 Kaiser P-86 150 kA side-riser, point-feed PB cells.
More than 30 HS Söderberg cells at Nadvoitsy, Russia, have been converted to
the Kaiser K-93 60 kA end-to-end, point-feed PB cell with six anodes, developed
at Tacoma and Chalmette (closed). These cells had magnetic compensation to reduce
the Bz fields due to the closeness of the adjacent row of pots in the same potroom.
Kaiser
developed and operated six P-80 195 kA (4) side-riser, point-feed PB cells with
16 anodes at Tacoma in 1981. These are no longer in operation.
Aluminium
Pechiney has developed eight types of PB cell technologies, from 70 kA to
300 kA, that are operating at aluminum smelters today: end-to-end, side-riser
PB cells AP-LN and AP-CM; side-by-side, end-riser PB cells AP-7, AP-9, AP-13,
and AP-14; and side-by-side, side-riser PB cells AP-18 and AP-30. In the cell
naming scheme, AP is Aluminium
Pechiney, and the potline amperage in kA is shortened by a factor of ten
(e.g., AP-13 designates 130 kA). Pechiney
has constructed the largest number of smelters (16) to date using its AP-18
and AP-30 PB cell technology.
The end-to-end VS Söderberg cells (AP-LN) at Lannemezan, France, in 1970 and
Alucam (AP-CM) at Edéa, Cameroon, in 1978 were retrofitted to PB cells with
central side-riser bus to provide magnetic compensation for the adjacent row
of pots in the same potroom for improved cell performance. The AP-7 and AP-9
PB cells (ADG) at St. Nicolas, Greece, were retrofitted from side work to point
feed in 1986. The AP-13 side-by-side, end-riser cells were built at Belem (Albras),
Ferndale (Intalco), Frederick (Eastalco), and Vlissingen (PNL). The AP-13 cells
at Ferndale (Intalco) were retrofitted in 1991 with magnetically compensated
busbars to reduce the high Bz associated with the high current flow around the
ends of the cell.
 |
|
Figure 6. A Pechiney 300 kA PB cell at St. Jean-de-Maurienne, France. |
The AP-30 300 kA five side-riser, point-feed PB cell technology
was developed at St. Jean-de-Maurienne, starting in 1981. Seven aluminum smelters
(2,040 cells) have been built using Pechiney AP-30 cells, and two more smelters
(720 cells) are under construction. The AP-30 smelters include Bahrain (Alba),
Alma (Alcan, under construction),
Septlles (Alouette), Richards Bay-Hillside (Alusaf), Boyne Island (Comalco),
Dunkirk, Deschambault (Lauralco), Mozal (under construction), and St. Jean-de-Maurienne
G-Line. Four of the AP-30 smelters have 20 pairs of anodes (two anodes per stem),
and three AP-30 smelters have 40 individual anodes per cell. With improvements
made to the cell lining, it has been reported that the amperage has been increased
in the AP-30 PB cells at several smelters to 325 kA.
The oldest Pechiney
aluminum smelter in operation is at St. Jean-de-Maurienne, which started up
in 1907; the start-up of the Auzat smelter was in 1914.
 |
|
Figure 7. Reynolds P20S PB cells at ALSCON, Ikot, Nigeria. |
VAW Aluminium
has developed five PB cell technologies that are in operation at smelters: end-to-end
PB cells Erftwerk, CA-120, and CA-165 and side-by-side, side-riser PB cells
CA180 and CA-240.
he original VAW cells at Rheinwerk
were based on the Erftwerk design with continuous PB anodes. All cells at the
Reinwerk smelter have been converted to PFPB with compensating three-riser asymmetric
bus to reduce the high Bz fields associated
with the closeness of the adjacent row of pots in the same potroom. In addition,
VAW actively participates
in the modernization and conversion of older cell technologies, such as the
conversion of 12 Söderberg cells to 165 kA end-to-end, side-riser, point-feed
PB cells at Bayside (Alusaf).
The Nordurál smelter at Grundartangi was built in 1998 using VAW CA-180 side-by-side,
point-feed PB cell technology from Töging. Significant parts of the potline
were purchased from the VAW
Töging plant, which was taken out of operation in 1994. Similarly, potline one
at Töging (100 cells, CA-120, 100 kA, end-to-end, center-work PB cells with
14 anodes) was purchased and relocated at the Danjiangkou smelter in China in
1999. An improved version of the CA-180 has been recently developed with a modified
shell, lining, and superstructure as well as fully graphitized cathode blocks
to allow it to operate at 210 kA.
VAW participated in the joint
development and construction of six CA-300, 300 kA, side-by-side, four side-riser,
point-feed PB cells with 32 anodes at the Sayansk Aluminum Smelter. These test
pots are no longer in operation.
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UNIVERSAL PREBAKE CELL NOMENCLATURE |
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Currently, there is no universal system
for the nomenclature and identification of prebake (PB) cell technologies.
Aluminum companies use their own naming systems, which differ widely
throughout the industry. Thus, the adoption of an acceptable universal
prebake nomenclature (UPBN) system is recommended for the naming of
future PB cells. Without the adoption of a UPBN system, the names
of prebake cells will become even more confused in the future in view
of recent mergers by aluminum companies and the renaming of existing
PB cells as they are modernized.
Using these guidelines, the Kaiser P-69, becomes KA-15-SE (Kaiser, 150 kA, side-by-side, end-riser PB cell) and the Alcoa A-697, becomes AA-18 (Alcoa, 180 kA, side-by-side, side-riser PB cell). |
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Nippon Light Metals developed P-160 160 kA, side-by-side, end-riser,
PB cell technologies that are used in aluminum smelters in China.
Montecatini developed P-115 and P-155 end-to-end, side-work PB cell technologies
that are in operation at four aluminum smelters: Bahrain (Alba); Fusina; Puerto
Madryn, Argentina (Aluar); and Porto Vesme, Sardinia. Most of the potlines have
been converted to point-feed technology. Several smelters have been retrofitted
with compensating bus to reduce the high Bz fields associated with the closeness
of the adjacent row of pots in the same potroom.
Elkem and Alcoa
converted one potline of VS Söderberg cells to a 155 kA PB cell at Mosjøen.
Sumitomo Aluminium Smelting developed S-170 side-by-side, end-riser, PB cell
technology that is used at two smelters at Boyne Island (Comalco)
and Kula Tanjung (Inalum). Retrofit improvements made at the Boyne Island smelter
include the use of longer anodes, a new sidewall and cathode design, point feed,
an improved control system, and increased amperage (200 kA).
The Aluminum Company
of Egypt (Egyptalum) at Nag Hammadi developed a 200 kA end-to-end PB cell
with asymmetric bus and side-riser magnetic compensation to replace the VS Söderberg
cells. More than 90 PB cells have been retrofitted and are in operation at the
smelter.
Venalum at Puerto Ordaz, Venezuela, developed five experimental V-350 side-by-side,
four side-riser, point-feed PB cells with 36 anodes that are operated at 320
kA in its developmental potline.
There are 14 aluminum smelters in the former Soviet Union,
the majority of which use Söderberg cells. There are six different types of
PB cell technologies in Russia: end-to-end PB cells C-50, C-125, C-160, C-175M2,
and C–190 and side-by-side, side-riser PB cell C-255. Most PB and Söderberg
cells were designed and developed by the VAMI Institute at St. Petersburg. The
letter “C” is used as a prefix for Russian PB cells (C-125 and C-160) and Söderberg
cells (C-2 and C-3).
The bus system of the end-to-end C-125, C-160, C-175M2, and C-190 PB cells has
been retrofitted with central-quarter riser and/or asymmetric compensating bus
to reduce the high Bz fields due to the closeness of the adjacent row of cells
in the same potroom.
The C-255, 255 kA side-by-side, side-riser, point-feed PB cell was developed
by VAMI in the late 1970s; they were prototyped at Volgograd in four developmental
cells, then built in Tadjik lines five and six. The C255M1, an upgraded version
of the C-255 cell, was built in Sayansk in line three.
Five developmental CA-300 300 kA side-by-side, side-riser, point-feed PB cells
were developed and operated at Sayansk in agreement with VAW.
These test cells are no longer in operation.
There are reported to be more than 100 aluminum smelters in
China, but the majority of the smelters are small and use Söderberg cell technology.
There are ten different PB cell technologies used in the aluminum smelters in
China: end-to-end PB cell P-60; end-to-end, quarter-riser PB cell P-115; side-by-side,
end-riser PB cells P-140, P-155, P-160, and P-160M; and side-by-side, side-riser
PB cells P-75, P-200, P-280, and P-320. In China, it is common to use the amperage
number for PB cells, such as 160 kA cell and 280 kA cell. In order to identify
different PB cell technologies for the same current, sometimes the plant name
is used before the amperage, such as Pingguo 160 kA cell and Qinghai 160 kA.
The P-60 end-to-end, side-work PB cells are in the test stage at more than ten
smelters for retrofitting the less efficient Söderberg cells. The bus system
of the side-by-side, end-riser P-160 PB cell has been retrofitted with compensating
bus to reduce the high Bz fields and resulting detrimental impact on the metal
pad due to the high amperage in the bus at the ends of the cells.
Two PB smelters; Danjiang P-115 end-to-end, point-feed cells; and Baiyin P-155
side-by-side, end-riser cells were transported to China from other countries.
The Guizhou P-160 side-by-side, end-riser point-feed cells are Nippon Light
Metals PB technology.
China is developing its own technology for retrofit improvements and the construction
of future smelters. A potline (30 cells) of the P320 side-by-side, six side-riser,
point-feed PB cells was put into operation at Pingguo in 1999.
Future PB cells will continue to become larger and operate at even higher amperages; testing has already begun at 400 kA, which is projected to be the next PB cell performance. However, larger PB cells have limitations. Some of the technical problems that will need to be addressed are
The author gratefully acknowledges and thanks colleagues in the aluminum industry for their contributions in the article: Yousuf Alfarsi of Dubal, Geoff Bearne of Comalco, Peter Entner of Alusuisse, Yiren Gan of China, Erik Jensen and Mikhail Khatskel of Reynolds, Vinko Potocnik of Alcan, Roger Johnson of Kaiser, Halvor Kvande of Hydro Aluminium, Michel Reverdy of Pechiney, Martin Segatz of VAW, and Barry Wheeless of Alcoa.
Alton Tabereaux is a department manager of Extractive Metallurgy at Smelter Technology Laboratory, Reynolds Metals.
For more information, contact A. Tabereaux, Reynolds Metals, Smelter Technology, 4276 Second Street, Muscle Shoals, Alabama 35661.Direct questions about this or any other JOM page to jom@tms.org.
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