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Title:
ARRANGEMENT FOR MEASURING ELECTRIC CURRENT IN AN INDIVIDUAL ELECTRODE IN AN ELECTROLYSIS SYSTEM
Document Type and Number:
WIPO Patent Application WO/2014/131946
Kind Code:
A1
Abstract:
The invention relates to a method and current measuring arrangement for measuring electric current flowing in an individual electrode in an electrolysis system. The electrolysis system comprises a plurality of interleaved electrodes (1, 2), cathodes (1) and anodes (2), arranged in an electrolysis cell (3) and immersed in electrolyte, said electrolysis system having a busbar (4) disposed on a separating cell wall (5) between each of the two adjacent cells to conduct electric current to the electrodes via a contact point (6) between the busbar and a hanger bar (7) of the electrode, and the current sensing arrangement comprises a magnetic field sensing means (8; 81, 82; 10) for measuring the magnetic field induced by said current. The magnetic field sensing means (8; 81, 82; 10) are arranged to sense the magnetic field substantially at the level of the contact point (6).

Inventors:
GRANT DUNCAN (GB)
BARKER MICHAEL H (IT)
NORDLUND LAURI (FI)
RANTALA ARI (FI)
VIRTANEN HENRI K (FI)
Application Number:
PCT/FI2014/050145
Publication Date:
September 04, 2014
Filing Date:
February 27, 2014
Export Citation:
Click for automatic bibliography generation   Help
Assignee:
OUTOTEC OYJ (FI)
International Classes:
C25B15/02; C25B9/63; C25B9/65; C25B15/06; G01R15/14; G01R15/18; G01R15/20
Domestic Patent References:
WO2012020243A12012-02-16
WO2014032085A12014-03-06
WO2013037899A12013-03-21
WO2012020243A12012-02-16
Foreign References:
US7445696B22008-11-04
US20100258435A12010-10-14
US6136177A2000-10-24
US7445696B22008-11-04
US6342136B12002-01-29
Other References:
WIECHMANN, E.P.; MORALES, A.S.; AQUEVEQUE, P.E.; BURGOS, R.P.: "Measurement of Cathodic Currents in Equipotential Inter-Cell Bars for Copper Electrowinning and Electrorefining Plants", INDUSTRY APPLICATIONS CONFERENCE, 2007. 42ND IAS ANNUAL MEETING. CONFERENCE RECORD OF THE 2007 IEEE, 23 September 2007 (2007-09-23), pages 2074 - 2079
WIECHMANN, MEASUREMENT OF CATHODIC CURRENTS....
See also references of EP 2961864A4
Attorney, Agent or Firm:
PAPULA OY (Helsinki, FI)
Download PDF:
Claims:
CLAIMS

1. A method of measuring electric current flowing in an individual electrode in an electrolysis system com- prising a plurality of interleaved electrodes (1, 2), cathodes (1) and anodes (2), arranged in an electroly¬ sis cell (3) and immersed in electrolyte, said elec¬ trolysis system having a busbar (4) disposed on a separating cell wall (5) between each of the two adjacent cells to conduct electric current to the electrodes via a contact point (6) between the busbar and a hang¬ er bar (7) of the electrode, and in which method the electric current of each electrode is measured by measuring the magnetic field induced by said current, characteri zed in that the magnetic field is sensed substantially at the level of the contact point (6) .

2. The method according to claim 1, character- i z e d in that the magnetic field is sensed with a magnetic circuit (8; 81, 82) being arranged to encircle the contact point (6) substantially in a horizontal plane at the level of the contact point. 3. The method according to claim 2, characteri zed in that the magnetic circuit (8) is an open loop current sensor.

4. The method according to claim 2, character- i z e d in that the magnetic circuit (8) is a closed loop current sensor.

5. The method according to any one of the claims 2 to 4, characteri zed in that the magnetic circuit (8) comprises a core of magnetic material formed as a first ring (81) surrounding the contact point (6), said ring being placed in recesses (9) formed in the busbar ( 4 ) .

6. The method according to any one of the claims 2 to 4, characteri zed in that the magnetic circuit is a core of magnetic material formed as a second ring (82) surrounding the contact point (6) and being bent, folded or formed in two or three dimensions to fit over the busbar (4) . 7. The method according to claim 1, characteri zed in that the magnetic field is sensed with a magnetic field sensor (10) arranged in the vicinity of the contact point (6) and in the horizontal plane. 8. The method according to claim 7, characteri zed in that the magnetic field is sensed with an array of magnetic field sensors (10) arranged in three dimensional space around the contact point (6) sub¬ stantially in the plane of the contact point at an an- gle in the range 0 to 75° with respect to horizontal.

9. The method according to claim 7 or 8, charac¬ teri zed in that a frame unit (11) of insulating, non-magnetic material is arranged to hold the magnetic field sensor (s) (10) in a predetermined position in three dimensional space with respect to the contact point ( 6) .

10. The method according to any one of the claims 1 to 9, characteri zed in that the magnetic field sensors are Hall effect sensors (10) and/or flux-gate type current sensors.

11. A current measuring arrangement for measuring electric current flowing in an individual electrode in an electrolysis system comprising a plurality of in- terleaved electrodes (1, 2), cathodes (1) and anodes (2), arranged in an electrolysis cell (3) and immersed in electrolyte, said electrolysis system having a bus¬ bar (4) disposed on a separating cell wall (5) between each of the two adjacent cells to conduct electric current to the electrodes via a contact point (6) be¬ tween the busbar and a hanger bar (7) of the electrode, and the current sensing arrangement comprises a magnetic field sensing means (8; 81, 82; 10) for meas¬ uring the magnetic field induced by said current, characteri zed in that the magnetic field sens¬ ing means (8; 81, 82; 10) are arranged to sense the magnetic field substantially at the level of the con¬ tact point ( 6) . 12. The arrangement according to claim 11, charac¬ teri zed in that the magnetic field sensing means comprise a magnetic circuit (8) arranged to encircle the contact point (6) substantially in the horizontal plane which is at the level of the contact point.

13. The arrangement according to claim 12, charac¬ teri zed in that the magnetic circuit (8) is an open loop current sensor. 14. The arrangement according to claim 12, charac¬ teri zed in that the magnetic circuit (8) is a closed loop current sensor.

15. The arrangement according to any one of the claims 12 to 14, characteri zed in the magnetic circuit

(8) comprises a core of magnetic material formed as a first ring (81) surrounding the contact point (6), said ring being placed in recesses (9) formed in the busbar ( 4 ) .

16. The arrangement according to any one of the claims 12 to 15, characteri zed in that the magnetic circuit is a core of magnetic material formed as a second ring (82) surrounding the contact point (6) and being bent or folded in two or three dimensions over the busbar ( 4 ) .

17. The arrangement according to claim 16, charac¬ teri zed in that the magnetic field sensing means comprises a magnetic field sensor (10) arranged in the vicinity of the contact point (6) .

18. The arrangement according to claim 17, charac¬ teri zed in that the arrangement comprises an array of magnetic field sensors (10) arranged around the contact point (6) substantially in a plane of the con¬ tact point.

19. The arrangement according to claim 17, charac¬ teri zed in that the array of magnetic field sen¬ sors (10) is arranged in a three dimensional space around the contact point (6) substantially in the plane of the contact point at an angle in the range 0 to 75° with respect to horizontal.

20. The arrangement according to claim 17, c h a r a c - teri zed in that the arrangement comprises a frame unit (11) of insulating, non-magnetic material to hold the magnetic field sensors (10) in a predetermined po¬ sition with respect to the contact point (6) . 21. The arrangement according to claim 20, charac¬ teri zed in that the frame unit (11) comprises a plurality of magnetic field sensors (10) arranged to measure magnetic field from a plurality of contact points ( 6) .

22. The arrangement according to claim 20 or 21, characteri zed in that the frame unit (11) com¬ prises one or more notches (12), each of said notches being arranged to accommodate an end of an electrode hanger bar (7) .

23. The arrangement according to claim 22, charac¬ teri zed in that the frame unit (11) comprises one or more notches (12) for one or more hanger bars (7) of anodes.

24. The arrangement according to claim 22, charac¬ teri zed in that the frame unit (11) comprises one or more notches (12) for one or more hanger bars (7) of cathodes.

25. The arrangement according to any one of the claims 22 to 24, characteri zed in that each notch (12) is arranged to accommodate an end of a hanger bar (7) with a play to allow installing of the frame unit (11) by dropping it into position on the busbar without having to remove the electrodes and to allow lifting the electrodes without having to remove the frame.

26. The arrangement according to any one of the claims 22 to 25, characteri zed in that each notch (12) is defined between two walls (13) which are parallel and opposite and at a distance from each other.

27. The arrangement according to claim 26, c h a r a c - teri zed in that two magnetic field sensors (10) , which are spaced from each other, are attached to each of the walls (13) .

28. The arrangement according to any one of the claims 20 to 27, characteri zed in that the frame unit

(11) comprises notches (12) for a number of hanger bars (7) of cathodes (1) and for a number of hanger bars (7) of anodes (2) . 29. The arrangement according to any one of the claims 20 to 28, characteri zed in that the arrangement comprises one frame unit (11) extending substantially to the whole length of the cell (3) .

30. The arrangement according to any one of the claims 20 to 28, characteri zed in that the arrangement comprises a plurality of frame units (11) arranged in a queue or row on the busbar.

31. The arrangement according to any one of the claims 20 to 30, characteri zed in that the frame unit

(11) comprises a microprocessor (15) for pre-analysis of the plurality of signals derived from the magnetic field sensors (10). 32. The arrangement according to claim 31, charac¬ teri zed in that the microprocessors (15) are ar¬ ranged to connect and exchange information by digital, analog or wireless means. 33. The arrangement according to any one of the claims 20 to 32, characteri zed in that the frame unit (11) comprises visual indicators (14) which are ar¬ ranged to indicate which electrodes have a problem as¬ sociated with them which requires attention of the tankhouse operators.

34. The arrangement according to claim 33, charac¬ teri zed in that the visual indicators (14) are controlled by the microprocessor (15) which is ar- ranged within the frame unit (11) .

35. The arrangement according to any one of the claims 31 to 34, characteri zed in that the micropro¬ cessor (15) is arranged to detect failure of a magnet¬ ic field sensor (10) and to reorganise its analysis of the remaining magnetic field sensor signal so that the frame unit (11) can continue to function.

36. The arrangement according to claim 35, charac¬ teri zed in that the microprocessor (15) is ar- ranged to provide a warning signal of the failure of a magnetic field sensor (10) .

37. The arrangement according to any one of the claims 31 to 34, characteri zed in that the arrangement comprises a central processing unit (16) arranged to receive signals from the microprocessors (15) of the frame units (11) .

38. The arrangement according to claim 37, c h a r a c - teri zed in that the microprocessors (15) are ar¬ ranged to connect and exchange information with the central processing unit (16) by digital, analog or wireless means. 39. The arrangement according to any one of the claims 20 to 38, characteri zed in that the frame unit (11) comprises temperature sensors (17) arranged to measure the temperature of the electrode hanger bars (7) .

40. The arrangement according to any one of the claims 20 to 39, characteri zed in that the frame unit (11) comprises temperature sensors (100) arranged to measure the temperature of the busbar (4) .

41. The arrangement according to any one of the claims 20 to 40, characteri zed in that the frame unit

(11) is powered by an external unit or host.

42. The arrangement according to any one of the claims 20 to 41, characteri zed in that the frame unit (11) comprises an electric energy storage device (18) .

43. The arrangement according to claim 42, charac¬ teri zed in that the energy storage device (18) is chargeable by energy harvesting from the ambient.

44. The arrangement according to any one of the claims 17 to 43, characteri zed in that the magnetic field sensors (10) are Hall effect sensors and/or flux-gate type current sensors.

Description:
ARRANGEMENT FOR MEASURING ELECTRIC CURRENT IN AN INDIVIDUAL ELECTRODE IN AN ELECTROLYSIS SYSTEM

FIELD OF THE INVENTION

The present invention relates to a method of measuring electric current flowing in an individual electrode in an electrolysis system. Further, the invention relates to a current measuring arrangement for measuring elec- trie current flowing in an individual electrode in an electrolysis system.

BACKGROUND OF THE INVENTION

In electrorefining (ER) and electrowinning (EW) elec- trodes are immersed in an electrolyte and an electric current is passed between them. The anode is made pos ¬ itive and the cathode made negative so that an elec ¬ tric current passes through the electrolyte from anode to cathode.

In electrorefining (ER) , the metal anode is soluble. That is to say that the metal enters into the electro ¬ lyte under the influence of the potential between the anode and cathode. For example, in the electrorefining of copper, the anode is made of impure metallic copper and copper ions enter the electrolyte from the anode. The copper ions, now in the electrolyte, are trans ¬ ported through or by the electrolyte to the cathode where they are deposited. The cathode may be of the same metal as the metal that is being deposited or it may be of a different metal. For example, in the elec- trorefining of copper it was at one time common to em- ploy a cathode made of copper. However, a stainless steel permanent cathode is now commonly employed which quickly becomes coated with copper and which from then on essentially performs as a copper cathode. The de- posited copper is mechanically removed or stripped from the permanent cathode and the permanent cathode reused. The copper deposited on the cathode is highly pure. Impurities that were in the impure anode may dissolve into the electrolyte or fall out as a solid as the anode is dissolved and may contain useful by ¬ products, for example, gold. Besides copper, metals purified by ER include gold, silver, lead, cobalt, nickel, tin and other metals. Electrowinning (EW) differs from electrorefining in that the metal sought is imported into the cells and is already contained within the electrolyte. In the example of copper, sulphuric acid is typically em ¬ ployed to dissolve copper from an oxide form of copper ore and the resulting liquor, after concentration, is imported into an electrowinning cell to have the cop ¬ per extracted. An anode and cathode are immersed in the electrolyte and a current is passed between them, again with the anode being positive and the cathode being negative. In electrowinning, the anode is not soluble but is made of an inert material. Typically a lead alloy anode is used in the case of copper elec ¬ trowinning. The cathode may be of the same metal that is being extracted from the electrolyte or it may be of a different material. For example, in the case of copper, copper cathodes may be used although stainless steel cathodes are commonly employed which quickly be- come coated in copper. Under of the influence of an electric current, the metal to be won leaves the elec ¬ trolyte solution and is deposited in a very pure form on the cathode. The electrolyte is circulated and con- centrated by this process having given up a large pro ¬ portion of its metal content. Besides copper, metals obtained by electrowinning include lead, gold, silver, zinc, chromium, cobalt, manganese, aluminium and other metals. For some metals, such as aluminium, the elec- trolyte is a molten material rather than an aqueous solution .

As an example of the voltages and current involved, in copper refining, the cell voltage is generally about 0.3V and in copper electrowinning is about 2.0V. In both cases the cathodic current density is about 300 A/m 2 and the area of each side of the cathode at pre ¬ sent is about 1 m 2 . These figures differ considerably for different metals and widely varying current densi- ties may be used for the same metal but the invention applies to the electrorefining and electrowinning of all metals.

In ER and EW the starting point is an anode juxtaposed to a cathode in an electrolyte contained in a tank. But many cathode plates and many anode plates may be used, interleaved, with all the anode plates connected in parallel and all the cathode plates connected in parallel contained within a single tank of electro- lyte. Electrically this still looks like a single cell and in the industry it is therefore commonly called a cell. In the ER and EW industry, "cell" is almost uni- versally used to mean a tank filled with anodes and cathodes in parallel. In the ER and EW industry, "tank" can mean the same as "cell", above, or it can mean the vessel alone, depending on the context. In tankhouses cells are connected electrically in se ¬ ries. A typical ER tankhouse might therefore require an electrical supply of the order of 36, 000 Amps at 200 Volts. The electrical circuit representing a typical tank- house is shown in Figure 1. Tanks 3, each containing one cell (composed of many cathodes 1 in parallel and many anodes 2 in parallel), are connected in series. A DC voltage source 19 is connected across the series circuit to drive the desired current through the cells 3. The total current is maintained at a desired value. Ideally, the current should divide equally between the cathodes 1. In practice, there is significant varia ¬ tion in the resistance of each cathode-anode current path and hence there are variations in the values of the individual cathode currents. This means in prac ¬ tice that the metal production process operates at be ¬ low optimum efficiency. More seriously, there is sometimes disruption to the operation of part of the cell when a short circuit de ¬ velops between an anode plate and a cathode plate. This is typically due to a nodule or dendrite of metal growing from a cathode plate and increasing in size until it connects with the adjacent anode plate. The nodule of metal has to be physically removed to permit normal operation to continue. Another disruption to normal production can occur when an individual cathode or individual anode becomes dis ¬ connected from the electrical circuit. As Figure 2 shows, the electrical connection to cathodes 1 and to anodes 2 is typically made through lugs or hanger bars 7 which project from each side of the electrodes. On the right side, the hanger bar 7 rests on a busbar 4 which forms part of the electrical circuit. The dis- connection is typically caused by corrosion or burning of the contact point 6 or by a foreign obstacle becom ¬ ing jammed between the hanger bar 7 and the busbar 4 or build up of sulfate between the hanger bar 7 and the busbar. On the left side, the other hanger bar 1' may either rest on an insulated supporting bar 4' or this bar may be a secondary busbar, also known as an equaliser bar, so that the electrode 1 is electrically connected through two paths so as to reduce the effect of a bad contact to one of the hanger bars 4.

A short circuit results in an unusually large amount of current flowing in the cathode 1 and the anode 2 which are electrically shorted together. Methods con ¬ ventionally employed to detect short circuits are less than ideal. One method is to detect the overheating of the electrodes resulting from the short circuit. This is less than satisfactory because damage to the elec ¬ trode, its hanger bars 7 or the busbar 4 may have re ¬ sulted due to a time delay before the short is detect- ed. This method will become even less acceptable as new, expensive, high-performance anodes, are introduced in ¬ to electrowinning processes. In electrowinning, inert lead anodes have been commonly used. In recent years mixed metal oxide (MMO) catalytically coated titanium anodes have been increasingly adopted because of their superior properties. However, the MMO coated titanium anodes are more expensive than lead based anodes and more easily damaged by the heat generated during shorting. It has therefore become imperative that problems with the process, in particular short cir ¬ cuits between electrodes, are identified very quickly. Furthermore it is desirable that circumstances likely to give rise to a short circuit are identified. One indicator of an incipient short circuit is a rise in cathode or anode current above its usual value. Hence current measurement with an accuracy and resolution suitable for detecting this rise in current is a tool for identifying dangerous situations and for prompting operator action to correct the situation.

Another method of detecting shorts is to have a worker patrol the tanks using a Gaussmeter to detect the high magnetic field produced by the short-circuit current. Due to restricted labour the patrol can often be orga ¬ nized only once per day or a maximum of few times per day. Therefore the short may go undetected for many hours, during which time production is lost, current efficiency decreases, risk of decreased cathode quali- ty increases and the electrodes, hanger bars and bus ¬ bars may be damaged. This method has also proved very inefficient because the patrol needs to check every cell including the cells that do not have any prob ¬ lems. Unnecessary walking on top the cells during the patrol may also cause electrode movement and thus new short circuits. It also increases the risk of acci- dents. Infrared cameras are also used either by the worker patrols or in overhead cranes to detect short circuits due to heat caused by high current. The meth ¬ od has often proved not to give the desired results in the tankhouse environment because of the long time de- lay in detecting a short and also availability issues of a crane for the monitoring task.

In order to detect short circuits and bad (open) con ¬ tacts there is a need to detect these problems at the level of individual cathodes or anodes by providing methods for measuring the current flowing in individu ¬ al electrodes.

In prior art, US 7,445,696 discloses an electrolytic cell current monitoring device and method, which de ¬ tects not only short circuits, but open circuits as well. The apparatus comprises magnetic field sensors, e.g. Hall effect sensors, that measure magnetic field strength generated around a conductor adapted to carry electrical current to or from an electrolytic cell. The magnetic field current sensors for each cathode may be arranged on a rail car device which operates above the cells to detect the shorts and open con ¬ tacts. Detection of current in all cathodes in the cell can be made simultaneously. The magnetic field sensor is brought at a distance above each electrode hanger bar aided by a capacitive proximity sensor. Further prior art is disclosed in an article "Measure ¬ ment of Cathodic Currents in Equipotential Inter-Cell Bars for Copper Electrowinning and Electrorefining Plants". Industry Applications Conference, 2007. 42nd IAS Annual Meeting. Conference Record of the 2007 IEEE; 23-27 Sept. 2007; Wiechmann, E.P., Morales, A.S.; Aqueveque, P.E.; Burgos, R.P. pp. 2074 - 2079, proposes a measurement technique for the cathodic cur- rents in a dog-bone type intercell bars using linear ratiometric Hall effect sensors and ferromagnetic flux concentrators. The article discloses that cathode currents may be measured by combining the magnetic flux sensors and flux concentrators.

Prior art arrangements for measuring the cathode or anode bar currents have employed Hall effect sensors in proximity to the electrode hanger bars or intercon- nectors between anodes and cathodes to sense the mag- netic field generated by these currents, thereby ob ¬ taining a signal proportional to the currents. Howev ¬ er, other current carrying conductors are usually in close proximity to the Hall effect sensors and the magnetic field they produce causes inaccuracy in the current measurement. The use of pieces of magnetic ma ¬ terial attached to the Hall effect sensor to concen ¬ trate flux through the sensor (as that disclosed in the above-mentioned article "Measurement of Cathodic Currents...." by Wiechmann et al.), may also channel un- wanted flux through the sensor. In short, the problem with the prior art methods and arrangements is that they do not provide sufficiently accurate measurement results of the electric current at the point of maximum current. The maximum current occurs at the contact point where the electrode hanger bar contacts the electric busbar. Further, the known methods, which measure the current from the electrode hanger bar from a distance above or underneath the hanger bar, are very susceptible to differences in the position of the hanger bar in the direction of the busbar in relation to the position of the magnetic field sensor. Also they have proved vulnerable to sig ¬ nificant measurement errors due to magnetic fields generated by adjacent cathodes. Therefore, the meas- urement accuracy obtained by prior art methods is bad and insufficient.

OBJECTIVE OF THE INVENTION

The objective of the invention is to eliminate the disadvantages mentioned above.

In particular, it is an objective of the present in ¬ vention to provide a method and arrangement which is able to measure accurately the current passing through the contact point of the electrode hanger bar and the electrical busbar.

Further, the objective of the invention is to provide method and arrangement for measuring the current en- tering or leaving the electrodes (cathodes and/or an ¬ odes) which will permit operators to detect early the presence of short circuits or open circuits. Further, the objective of the invention is to provide method and arrangement, which enable, due to the suf ¬ ficiently accurate current measurement, that the growth of the metal nodules or dendrites which lead to a short circuit may be detected before the short circuit occurs, allowing action to be taken to pre ¬ vent a short occurring. Further, the objective of the invention is to provide method and arrangement, which enable, due to the suf ¬ ficiently accurate current measurement, that high re ¬ sistance contacts (between the hanger bar contacts and their respective busbars) can be identified and early corrective action can be taken.

Further, the objective of the invention is to provide method and arrangement which enable, due to the suffi ¬ ciently accurate current measurement, that the meas- urement can be of use for process control, either through real time adjustment of current flow or by im ¬ provements in plant operation resulting from analysis of the data. Further, the objective of the invention is to provide method and arrangement, which, due to the sufficiently accurate current measurement, permits process analy ¬ sis, and if required, dynamic process control, as well as the detection of incipient short circuits and actu- al short circuits and the detection of open circuits. The Table 1 below shows the estimated current measure ¬ ment accuracy required for the various objectives men ¬ tioned above. This invention aims to make current measurements of the highest accuracy thereby permit- ting process analysis, and if required, dynamic pro ¬ cess control, as well as the detection of incipient short circuits and actual short circuits and the de ¬ tection of open circuits. Table 1

SUMMARY OF THE INVENTION

According to a first aspect, the present invention provides a method of measuring electric current flow ¬ ing in an individual electrode in an electrolysis sys ¬ tem comprising a plurality of interleaved electrodes, cathodes and anodes, arranged in an electrolysis cell and immersed in electrolyte, said electrolysis system having a busbar disposed on a separating cell wall between each of the two adjacent cells to conduct elec ¬ tric current to the electrodes via a contact point be ¬ tween the busbar and a hanger bar of the electrode, and in which method the electric current of each elec ¬ trode is measured by measuring the magnetic field in ¬ duced by said current. "The contact point" is the site where the hanger bar makes contact with the respective busbar element. According to the invention the magnet ¬ ic field is sensed substantially at the level of the contact point.

According to a second aspect, the present invention provides a current measuring arrangement for measuring electric current flowing in an individual electrode in an electrolysis system comprising a plurality of in ¬ terleaved electrodes, cathodes and anodes, arranged in an electrolysis cell and immersed in an electrolyte, said electrolysis system having a busbar disposed on a separating cell wall between each of the two adjacent cells to conduct electric current to the electrodes via a contact point between the busbar and a hanger bar of the electrode, and the current sensing arrange- ment comprises a magnetic field sensing means for measuring the magnetic field induced by said current. According to the invention the magnetic field sensing means are arranged to sense the magnetic field sub ¬ stantially at the level of the contact point.

The advantage of the invention is that very accurate measurement results of the current passing via the contact points can be obtained for the detection of short circuits, incipient short circuits, open cir- cuits and incipient open circuits. This permits opera ¬ tors to take an early corrective action before any damage occurs. The invention may be fitted during con- struction of new ER and EW plants, or retrofitted to an existing ER or EW plant. A further advantage of the invention is to identify to operators the exact loca ¬ tion of a fault or incipient fault thereby eliminating the need for operator patrols which are wasteful of labour and potentially damaging to the cells.

In an embodiment of the method, the magnetic field is sensed with a magnetic circuit being arranged to en- circle the contact point substantially in a horizontal plane at the level of the contact point.

In an embodiment of the method, the magnetic circuit is an open loop current sensor.

In an embodiment of the method, the magnetic circuit is a closed loop current sensor.

In an embodiment of the method, the magnetic circuit comprises a core of magnetic material formed as a first ring surrounding the contact point, said ring being placed in recesses formed in the busbar.

In an embodiment of the method, the magnetic circuit is a core of magnetic material formed as a second ring surrounding the contact point and being bent, folded or formed in two or three dimensions to fit over the busbar profile. In an embodiment of the method, the magnetic field is sensed with a magnetic field sensor arranged in the vicinity of the contact point and in the horizontal plane. For fabrication reasons, the sensor may need to be located a 3D coordinate above the horizontal plane of the contact point. Such a location may be less than optimum for measurement signal, but more practical for physically positioning a sensor, i.e. a position which is already not occupied by other equipment typically present on the top of an EW cell including for example busbar, hanger bars, insulators, electrode lifting hooks or other cell top furniture and will vary from tankhouse to tankhouse. The angle of the sensor to the horizontal plane of the contact point may then be in the range of 0 to 75°. 0 degrees means that the sensor is in the same plane as the contact point, 75 degrees means almost directly above the contact point.

In an embodiment of the method, the magnetic field is sensed with an array of magnetic field sensors ar ¬ ranged in three dimensional space around the contact point substantially in the horizontal plane of the contact point, but also at an angle in the range 0 to 75° .

In an embodiment of the method, the magnetic field is sensed with an array of magnetic field sensors ar- ranged around the contact point substantially in the horizontal plane of the contact point.

In an embodiment of the method, a frame unit of insu ¬ lating, non-magnetic material is arranged to hold the magnetic field sensor (s) in a predetermined position in three dimensional space with respect to the contact point . In an embodiment of the method, the magnetic field sensors are Hall effect sensors and/or flux-gate type current sensors.

In an embodiment of the arrangement, the magnetic field sensing means comprise a magnetic circuit ar ¬ ranged to encircle the contact point substantially in the horizontal plane which is at the level of the con- tact point.

In an embodiment of the arrangement, the magnetic cir ¬ cuit is an open loop current sensor. In an embodiment of the arrangement, the magnetic cir ¬ cuit is a closed loop current sensor.

In an embodiment of the arrangement, the magnetic cir ¬ cuit comprises a core of magnetic material formed as a first ring surrounding the contact point, said ring being placed in recesses formed in the busbar.

In an embodiment of the arrangement, the magnetic cir ¬ cuit is a core of magnetic material formed as a second ring surrounding the contact point and being bent or folded in two or three dimensions over the busbar.

In an embodiment of the arrangement, the magnetic field sensing comprises a magnetic field sensor ar ¬ ranged in the vicinity of the contact point. In an embodiment of the arrangement, the arrangement comprises an array of magnetic field sensors arranged around the contact point substantially in a plane of the contact point.

In an embodiment of the arrangement, the array of mag ¬ netic field sensors is arranged in a three dimensional space around the contact point substantially in the plane of the contact point at an angle in the range 0 to 75° with respect to horizontal.

In an embodiment of the arrangement, the arrangement comprises an array of magnetic field sensors arranged around the contact point substantially in the horizon- tal plane at the level of the contact point.

In an embodiment of the arrangement, the arrangement comprises a frame unit of insulating, non-magnetic ma ¬ terial to hold the magnetic field sensors in a prede- termined position with respect to the contact point.

In an embodiment of the arrangement, the frame unit comprises a plurality of magnetic field sensors ar ¬ ranged to measure magnetic field from a plurality of contact points.

In an embodiment of the arrangement, the frame unit comprises one or more notches, each of said notches being arranged to accommodate an end of an electrode hanger bar. In an embodiment of the arrangement, the frame unit comprises one or more notches for one or more hanger bars of cathodes. In an embodiment of the arrangement, the frame unit comprises one or more notches for one or more hanger bars of anodes.

In an embodiment of the arrangement, each notch is ar- ranged to accommodate an end of a hanger bar with a play to allow installing of the frame unit by dropping it into position on the busbar without having to remove the electrodes and to allow lifting the elec ¬ trodes without having to remove the frame.

In an embodiment of the arrangement, each notch is de ¬ fined between two walls which are parallel and oppo ¬ site and at a distance from each other. In an embodiment of the arrangement, two magnetic field sensors, which are spaced from each other, are attached to each of the walls.

In an embodiment of the arrangement, the frame unit comprises notches for a number of hanger bars of cath ¬ odes and for a number of hanger bars of anodes.

In an embodiment of the arrangement, the arrangement comprises a plurality of frame units arranged in a queue or row on the busbar. In an embodiment of the arrangement, the frame unit comprises a microprocessor for pre-analysis of the plurality of signals derived from the magnetic field sensors .

In an embodiment of the arrangement, the frame unit microprocessors connect and exchange information by digital, analog or wireless means. In an embodiment of the arrangement, the frame unit microprocessors connect and exchange information with a host microprocessor by digital, analog or wireless means . In an embodiment of the arrangement, the frame unit comprises visual indicators which are arranged to in ¬ dicate which electrodes have a problem associated with them which requires attention of the tankhouse opera ¬ tors .

In an embodiment of the arrangement, the visual indi ¬ cators are controlled by the microprocessor which is arranged within the frame unit. In an embodiment of the arrangement, the microproces ¬ sor is arranged to detect failure of a magnetic field sensor and to reorganize its analysis of the remaining magnetic field sensor signal so that the frame unit can continue to function. In an embodiment of the arrangement, the microproces ¬ sor is arranged to provide a warning signal of the failure of a magnetic field sensor. In an embodiment of the arrangement, the arrangement comprises a central processing unit arranged to re ¬ ceive signals from the microprocessors of the frame units . In an embodiment of the arrangement, the frame unit comprises temperature sensors arranged to measure the temperature of the electrode hanger bars.

In an embodiment of the arrangement, the frame unit comprises temperature sensors arranged to measure the temperature of the bus bar.

In an embodiment of the arrangement, the frame unit is powered by external unit or host.

In an embodiment of the arrangement, the frame unit comprises an electrical energy storage device.

In an embodiment of the arrangement, the energy stor ¬ age is chargeable by energy harvesting from the ambi ¬ ent .

In an embodiment of the arrangement, the magnetic field sensors are Hall effect sensors and/or flux-gate type current sensors. BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are included to pro ¬ vide a further understanding of the invention and con- stitute a part of this specification, illustrate em ¬ bodiments of the invention and together with the de ¬ scription help to explain the principles of the inven ¬ tion. In the drawings: Figure 1 is a schematic representation of the electri ¬ cal circuit of a tankhouse,

Figure 2 is a cross-section of an electrolysis cell with an electrode immersed in electrolyte,

Figure 3 is a schematic illustration of an open loop current sensor,

Figure 4 is a schematic illustration of a closed loop current sensor,

Figure 5 shows a top view of a single-plane rigid cur ¬ rent sensor (open loop or closed loop) fitted around a busbar - hanger bar contact point with recesses cut in the busbar to accommodate the sensor,

Figure 6 shows a cross-section VI-VI from Figure 5,

Figure 7 shows how an open loop or closed loop current sensor which comprises a core bent in a third dimen ¬ sion to permit it to be fitted around a contact point without cutting of the busbar or the electrode hanger bar,

Figure 8 shows how an open loop or closed loop cur- rent sensor which comprises a core bent and twisted to permit it to be fitted around a contact point without cutting of the busbar or the electrode hanger bar,

Figure 9 is a schematic illustration of a Hall effect sensor,

Figure 10 shows four Hall effect sensors deployed around a busbar to hanger bar contact point at 90 de ¬ grees separation,

Figure 11 shows two Hall effect sensors deployed around a busbar to hanger bar contact point at 180 de ¬ grees separation, Figure 12 shows four Hall effect sensors deployed around a contact point at 120 degrees, 60 degrees, 120 degrees and 60 degrees separation,

Figure 13 shows a further embodiment in which the Hall effect sensors may be mounted in a non-optimal way for the convenience of assembly,

Figure 14 shows how the Hall effect sensors may be mounted at an angle vertically to the ideal to facili- tate mounting, Figure 15 shows a cross section of a double contact busbar system with cathode and anode hanger bars having their contact points to the conductors, and a frame unit having magnetic field sensors to detect the current passing through the contact points,

Figure 16 shows in plan view the double contact busbar system of Figure 16 wherein the frame unit covers four cathodes and anodes with four Hall sensors deployed around each busbar - hanger bar contact point,

Figure 17 shows in axonometric view an embodiment of the frame units which are designed so as to be able to be dropped onto a set of cathode and anode hanger bars while the ER or EW system is in operation and which allows unhindered lifting of anodes and cathodes, and

Figure 18 is a block diagram of one embodiment of the arrangement of the invention.

DETAILED DESCRIPTION OF THE INVENTION

In one embodiment of the invention, as also shown in Figures 5 to 8, the magnetic field is sensed at the level of the contact point 6 between a hanger bar 7 of an electrode 1 and/or 2 and the busbar 4 with a mag ¬ netic circuit 8; 8 1 , 8 2 which is arranged to encircle the contact point 6 substantially in a horizontal plane substantially at the level of the contact point. The magnetic circuit may be used as an open loop cur- rent sensor or as a closed loop current sensor. This permits accurate measurements to be made on electrode currents . Figure 3 shows the well-known principle of an open loop magnetic circuit for current measurement. In this sensor the current-carrying conductor 20 passes through a magnetic circuit 8. The current I in the conductor 20 creates a magnetic flux in the magnetic circuit 8 which is proportional to the current in the conductor 20. The magnetic flux density in a gap 21 in the magnetic circuit 8 is measured by a Hall effect magnetic field sensor 10. The sensor 10 outputs a sig ¬ nal 22 which is proportional to the magnetic flux den ¬ sity in the gap 21 and hence to the current in the conductor 20. Figure 4 shows the well-known principle of a closed loop magnetic circuit for current measurement. In this sensor the current-carrying conductor 20 passes through a magnetic circuit 8. The current in the con ¬ ductor 20 tends to create a magnetic flux in the mag- netic circuit 8. This tends to alter the magnetic flux density in a gap 21. The output of the Hall effect sensor 10 in the gap 21 outputs a signal as a result of this change in flux density in the gap 21. This signal is amplified by amplifier 23 which supplies current to the coil 24 in such a sense that its Am ¬ pere-turn contribution to the magnetization of the magnetic circuit 8 opposes the Ampere-Turn contribu ¬ tion of the current in conductor 20 to the magnetiza ¬ tion of the magnetic core 8. A balance is established between these competing Ampere-turns so that the flux in the core 8 remains close to zero. The current in the coil 24 passes through a resistor 25 to generate an output voltage signal 26 which is proportional to the current in coil 24 and also proportional to the current in the conductor 20. Figures 5 and 6 show a typical cathode or anode hanger bar 7 resting on a busbar 4 from which it obtains current or into which it delivers current. In some in ¬ stances, current flow at the contact points will be unidirectional and in some other instances it will be bidirectional (for example in double-contact busbar systems, see also Figures 15 and 16) . Since the bottom of the hanger bar 7 is often curved and the top of the busbar 4 is often curved, current flows through a contact point 6 between the two. If either the hanger bar 7 is flat-bottomed the contact point 6 is likely to be elongated. A magnetic circuit 8, which in this embod ¬ iment is a rectangular core of magnetic material formed as a first ring 8 1 , encircles the contact point 6. Since the magnetic circuit 8 1 is rigid and essen- tially two-dimensional (i.e. flat), recesses 9 have been cut in the busbar 4 to accommodate the magnetic circuit ring 8 1 to enable the magnetic field to be sensed at the level of the contact point 6. The ar ¬ rangement of the magnetic circuit of Figures 5 and 6 is suitable to be installed during construction of new ER and EW plant.

Figure 7 shows the arrangement described in Figure 6 but with a magnetic circuit 8 which a core of magnetic material formed as a second ring 8 2 which is three- dimensionally bent, folded or formed to curve over the busbar 4. Thereby it is possible to avoid cutting re- cesses in the bus bar 4. Figure 8 shows how the second ring core of the magnetic circuit 8 2 may be twisted as well as bent to obtain a more convenient shape when the magnetic circuit is extended beyond the hanger bar 7. The embodiments of Figures 7 and 8 are important when retrofitting to an existing ER or EW plant is the objective. In an existing electrorefining plant the magnetic circuit of Figure 7 or 8 may be fitted when the cathodes are harvested or the anodes changed or during cell cleaning. In existing electrowinning plant the magnetic circuits may be fitted when cathodes are harvested. Furthermore, the facility to bend the magnetic circuit 8 2 in three dimensions affords the opportunity to locate the limb 27, which contains the magnetic flux sensor 10, in a position where it is un ¬ likely to collect magnetic flux created by electric currents other than the current passing through the contact point 6 which is measured. With respect to open loop and closed loop sensors, when selecting the position of the sensor gap, one should realize that magnetic flux generated by current other than that to be measured should be encouraged to pass through parts of the sensor magnetic which do not include the gap containing the Hall effect (or other) sensor. Also the gap in the magnetic circuit contain ¬ ing the Hall effect sensor (or other) should be locat ¬ ed in a part of the magnetic circuit which is not prone to carrying magnetic flux generated by currents other than the one to be measured. Further, it is de ¬ sirable that the Hall effect sensor (or other) to be located as far away as possible from sources of heat. Further, with respect to open loop and closed loop sensors, when selecting the type of sensor to put in the gap of the magnetic circuit, one should realize that that there are also other options for the sensor in the magnetic circuit gap other than Hall effect sensors - for example flux-gate type sensors. Hall ef ¬ fect sensors may be combined in an integrated circuit with a range of other facilities, such as temperature compensation, calibration factor memory, digital output, non-ratiometric output, etc. Such facilities come at a cost and the designer when electing to use the more sophisticated Hall effect sensors will decide if the benefits merit the extra cost.

Also with respect to open loop and closed loop sen ¬ sors, when selecting the material for the core, one should realize that the measurements of current to be made in electrolysis do not require a high bandwidth - the measurement being essentially that of direct cur ¬ rent only. Hence bandwidth can be sacrificed to the benefit of other characteristics of the sensor. Low remanence magnetic material for the core is desirable. Low remanence material is generally more expensive than conventional silicon steel (such as is used for transformer laminations) . Ferrite cores are also pos ¬ sible to be used but they are manufactured in specific shapes (for example E-cores and torroids) and it would be expensive to require a ferrite core manufacturer to tool-up for cores which have a specific three- dimensional shape. Remanence in the magnetic material can be mitigated by the well-known process of degauss- ing which some current sensor management integrated circuits offer as a built-in facility.

High accuracy results from measuring the current in each electrode at a location where it is concentrated in a point. Low cost of the magnetic circuit by choice of a magnetic material which optimises performance at dc rather than ac. Using the flexibility of the mag ¬ netic material chosen permits the magnetic material to be bent in three dimensions so as to allow the current sensor to be fitted around the contact point without cutting the busbar or electrode hanger bar.

An embodiment of the invention relates to the use of Hall effect sensors to measure currents in a multi ¬ plicity of adjacent electrodes within an electrolysis process .

Figure 9 shows a typical Hall effect sensor 10. It is sensitive to magnetic flux passing through it in the x axis but not in the y or z axis. This can be used to discriminate between flux produced by current flowing in different planes. With reference to Figure 10, in an embodiment of the invention an array of magnetic field sensors 10 is ar ¬ ranged around the contact point 6 substantially in the horizontal plane at the level of the contact point. Figure 10 shows an array of Hall effect transducers 1 (top view) deployed around a current-carrying conduc ¬ tor which in this invention may be the contact point 6 (labeled A) between an electrode hanger bar and a bus- bar (not shown) . The Hall effect sensors 10 are mount ¬ ed with their edge (axis z, see Figure 9) pointing to ¬ wards the centre line of the contact point 6. The four Hall effect sensors 10 are equidistant from the con- tact point 6. Lines of magnetic flux 28 created by the current passing via the contact point 6 pass through the sensitive x axis of the Hall effect sensors 10. The output signals from the Hall effect sensors are added together (summed) either through analogue means or by being converted to digital data signals and add ¬ ed together in a microprocessor. The sum of these signals is a measure of the current flowing at the con ¬ tact point 6 which is relatively insensitive to dis ¬ placement of the contact point 6 within the array of Hall sensors 10. Additionally, if another conductor 29 (labeled B) is in the vicinity of the array of the Hall effect sensors 10, and generating magnetic flux in the same plane as that generated by conductor A, the sum of the sensor 10 outputs will be little af- fected by the magnetic flux 30 from conductor B. As Figure 10 shows, flux lines 30 pass through pairs of sensors 10 in opposing directions and therefore the signal they generate in a pair of sensors sums to zero and the signal generated in the sum of all four of the sensors 10 will also sum to zero.

In the interests of economy, the number of sensors 10 can be reduced to two as shown in Figure 11. However, the magnitude of the final signal will be halved. Al- so, the total signal (the sum of the two signals) will not be so insensitive to displacement of contact point 6 in all directions. Also, as shown, the sensors 10 will be less insensitive to flux generated by conduc ¬ tor B but if the position of conductor B is rotated 90 degrees about conductor A, the array signal will be ¬ come sensitive to flux from conductor B.

Similarly, if the angle between sensors in the array is changed to 120°, 60°, 120° and 60° as shown in Fig ¬ ure 12, there will be similar loss of the array's ca ¬ pability to reject displacement of the conductor A with respect to the array and of the array's capabil ¬ ity to reject the effect of flux from conductor B when B is in certain positions with respect to conductor A. However, where greatest accuracy of current measure ¬ ment is not sought and it is convenient for construc- tional reasons to use a deployment as shown in Figure 12, the loss of accuracy and unwanted signal rejection may be acceptable.

Figure 13 shows a further example of placement of the magnetic field sensors 10. The arrangement comprises a frame unit 11 of insulating, non-magnetic material to hold the magnetic field sensors 10 in a predetermined position with respect to the contact point 6. The frame unit 11 comprises a notch 12 arranged to accom- modate an electrode hanger bar 7 with a play. The notch 12 is defined between two walls 13 which are parallel and opposite and at a distance from each oth ¬ er. Two magnetic field sensors 10, which are spaced from each other, are attached to each of the walls 13. The sensors 10 are aligned with side walls 13 of a frame unit 11 which are aligned with the hanger bar 7 of an electrode which is perpendicularto the busbar 4. As can be seen from Figure 13, since the sensors 10 are aligned with walls 13 they are not mounted with their edge (axis z, see Figure 9) pointing towards the centre line of the contact point 6 (as in Figure 10) . This placement of the sensors 10 is not ideal but may have advantages with respect to mounting.

Figure 14 shows a further example of placement of the magnetic field sensors 10. The sensors 10 are aligned vertically with the wall 13 of the frame unit 11 at a small angle to the vertical. A further non-ideality is occasioned by the possible elevation of the sensors 10 above the horizontal plane of the contact point 6 should it not be possible to mount them exactly along that plane for physical reasons.

A cathode or anode contact point 6 will require four Hall effect sensors 10 for best performance measure ¬ ment of the current flowing through it.

Figures 15 and 16 show the arrangement of one embodi ¬ ment of the invention adapted to be used in connection with a double-contact busbar system, trade name Ou- totec DoubleContact™, (also disclosed in US 6,342,136 Bl) together with hanger bars 7 of cathodes 1 and anodes 2 positioned on top of the busbar. The double- contact busbar system comprises a main intercell bus ¬ bar 4, placed on a lower insulator 31, to conduct current from anodes 2 (on the left) to cathodes 1 (on the right) . Further the system comprises a first equalizer busbar 32, placed on the lower insulator 31, for anode contacts and a second equalizer bar 33 for cathode contacts, said second equalizer 33 bar being placed on a second insulator 34 which is on the main intercell busbar 4. The double-contact busbar system aids the current distribution in the cell to be even across all electrodes. This system also provides the current with multiple paths to find the lowest resistance route be ¬ tween anode and cathode as the current goes from the busbar to the electroplating process. Figure 16 also illustrates the direction of the cur ¬ rent at the contact points 6. In the contact points 6 of the anodes 2 to the main busbar 4 the current flows unidirectionally from the main busbar 4 to the anodes 2 (out of the page) . In the contact points 6 of the cathodes 1 to the main busbar 4 the current flows from the the cathodes 1 to main busbar 4 unidirectionally (into the page) . In the contact points 6 of the cath ¬ odes 1 to the first equalizer bar 33 the current flow is birectional. Likewise, in the contact points 6 of the anodes 2 to the second equalizer bar 32 the cur ¬ rent flow is birectional.

Figures 15 and 16 show a frame unit 11 of insulating, non-magnetic material. The frame unit 11 holds the magnetic field sensors 10 in a predetermined position with respect to the contact point 6. The frame unit 11 comprises a plurality of magnetic field sensors 10 arranged to measure magnetic field from a plurality of contact points 6. The frame unit 11 comprises a plu- rality of notches 12, each of which is arranged to ac ¬ commodate one end of an electrode hanger bar 7 with a play to allow installing of the frame by dropping it into position on the busbar without having to remove the electrodes and to allow lifting the electrodes without having to remove the frame. In this embodiment the frame unit 11 comprises notches 12 for four ends of hanger bars 7 of cathodes 1 and for four ends of hanger bars 7 of anodes 2. Each notch 12 is defined between two walls 13 which are parallel and opposite and at a distance from each other. A pair of magnetic field sensors 10, e.g. Hall effect sensors, which are spaced from each other, are attached to each of the walls 13.

In the embodiment of Figures 15 and 16 the current passing through the contact points 6 of both cathodes 1 and anodes 2 are monitored, though it is a matter of choice whether cathodes or anodes or both are moni ¬ tored. The more contact points 6 that are monitored, the better will be the ability of the system to sup ¬ press inaccuracy in any particular current measurement due to the presence of currents in adjacent conduc ¬ tors .

The frame unit 11, as shown in Figure 16, permits the anodes 2 and cathodes 1 to be lifted from the cell 3 without hindrance. Appropriate design of the frame unit 11 also allows the frame unit to be dropped into position on a working ER or EW system without interfering with production. Clearly this is an advantage where the current measuring system is retrofitted to an existing ER or EW plant. The frame units 11 may be constructed so heavy that they stay stationary on the busbar and are not lifted during harvesting even if the hanger bars frictionally contact the frame unit. In addition, or alternatively, the frame units can be equipped with quick release couplings to fix them to the cell wall or to the busbar.

Figure 17 shows a row or queue of equal frame units 11, as described in connection with Figure 16, placed on the intercell busbar. In Figure 17 only hanger bars 7 of cathodes 1 resting on the busbar are shown and hanger bars of the anodes are not shown. The frame units 11 are so designed that they may be dropped into position without interfering with production. Also they are so designed that the raising of cathodes and anodes is unhindered by the presence of the frame units 11. The frame unit 11 can comprise visual indi ¬ cators 14 which are arranged to indicate which elec ¬ trodes have a problem associated with them which re ¬ quires attention. Where the frame unit 11 is endowed with visual indicators 14 (e.g. LEDs on its upper sur- face) it will be understood that these visual indica ¬ tors 14 can provide information in ways other than being simply on or off. For example they may flash, at various rates, or change colour or employ a range of LEDs of various colours. Furthermore, a visual indica- tor 14 may be an infra-red light emitter so that in ¬ formation may be conveyed to a hand-held operator in ¬ strument or to a fixed infrared receiver. Visual indi ¬ cators 14 may be LEDs located on the top of each frame unit 11 and can be used as a visual indicator of the position of anodes or cathodes that are in distress and need attention from an operator. The data trans- mitted back to the control room can also show an oper ¬ ator which anodes or cathodes need to be serviced.

Referring also to Figure 18, the frame unit 11 may al- so comprise a microprocessor 15 for pre-analysis of the plurality of signals derived from the magnetic field sensors 10 so that only derived current measure ¬ ment signals need to be transmitted to a central pro ¬ cessing station 16. In some other embodiment, the mi- croprocessor does not necessarily be physically fixed to the frame unit. The microprocessor can also be ex ¬ ternal and outside the frame unit. The microprocessor 15 may also be programmed to contain individual ID and location information. The visual indicators 14 are controlled by the microprocessor 15. The microproces ¬ sor within each frame unit 11 is given the capability to detect failure of a Hall effect sensor 10 and to reorganize its analysis of the remaining Hall sensor signal so that the frame unit 11 can continue to func- tion, albeit in a slightly degraded manner, and at the same time, where possible, provide a warning signal to the central control room of the failure and degrada ¬ tion so that the frame unit may be replaced during a period of scheduled maintenance. The arrangement com- prises a central processing unit 16 arranged to re ¬ ceive signals from the microprocessors 15 of the frame units 11.

An algorithm optionally within the operating programme of the microprocessor contained within the frame unit can be arranged to create a record of each anode and/or cathode current against time and analyses said record to look for the profile of a short circuit in the process of developing.

The frame unit 11 may also comprise temperature sen- sors 17 arranged to measure the temperature of the electrode hanger bars 7, bus bars 4 or the frame unit 11. Temperature sensors 17 can be connected to the mi ¬ croprocessor 15 of the frame unit and hence also com ¬ municate with the central control facility 16. The temperature sensors 17 are preferentially located close to the electrode hanger bars 7. The hanger bars 7 are the most likely source of heating of the frame unit 11. This heating could damage the Hall effect sensors 10. Hence an early warning of rising tempera- ture will enable an operator to take corrective action and avoid damage to the Hall sensors and other elec ¬ tronic components within the frame unit. Additionally hot hanger bars are an indication of a short circuit between electrodes. Cold hanger bars could be an indi- cation of an open circuit. Hence the temperature sen ¬ sors are another source of information about the con ¬ dition of the electrolysis cell. The Hall effect sen ¬ sors and the temperature sensors may therefore cooper ¬ ate to provide plant operators with a warning of actu- al or impending problems. Optionally, the signals from the Hall effect sensors and the temperature sensors may be analysed by the microprocessor in the frame unit to provide a simple warning of a problem at that location to the control room or via a visual indicator mounts on the frame unit. The frame unit may operate even if no current sensor is in operation so that it depends entirely upon temperature detection. Some characteristics of the Hall effect sensors are temper ¬ ature dependent. The temperature readings sent to the microprocessor can therefore be used to correct for temperature the signals arriving from the Hall effect sensors. Thermistors, thermocouples, digital sensors or infrared sensors may all be used as temperature sensors .

Further, the frame unit 11 may comprise an electric energy storage 18 which may be chargeable by energy harvesting from the ambient or externally via normal power supply. A typical Hall effect sensor will draw approximately 10 mA in operation. If a frame unit should encompass four cathodes and four anodes, each surrounded by four Hall effect sensors, the total num ¬ ber of Hall effect sensors employed will be 32. The total current drawn by the Hall effect sensors if all are operated continuously will be 320 mA. This may be inconveniently large. Each Hall effect sensor or array of Hall effect sensors may therefore be connected to its power supply by an electronic switch (for example, a MOSFET) which is under the control of the micropro ¬ cessor in the frame unit. Hence only those Hall sen ¬ sors for which a reading is required at any time are activated by the microprocessor.

Since electrolysis varies with time only slowly, read ¬ ings of the current (and any other measurements) need only be taken at large intervals of time. Furthermore, readings can be obtained from the Hall sensors in fractions of a second. The microprocessor can be ar ¬ ranged to spend most of the time in sleep mode using only a tiny amount of power with all other electronics in the frame unit turned off. Hence the average power consumption of the electronics contained within the frame unit can be very low. The frame unit can spend nearly all the time in hibernation using only a few yW of power. If there is an energy storage unit within the frame units (for example a suitably sized capaci ¬ tor or rechargeable battery) this can be trickle charged from a low power source or via a 4normal power supply. It may be possible to obtain this trickle charge by energy harvesting. There are a number of ways this can be achieved (e.g. ripple current, photo ¬ voltaic source, thermal pile or Peltier generator us ¬ ing the heat from the electrolysis tank) . In addition this stored energy may also be used to transmit the data obtained wirelessly if desired by activating a radio transmitter for a very short time (typically a fraction of a second) . A further embodiment may also be that on the base of the frame unit, spring contacts which press against the busbar conducting elements. The purpose of these contacts is twofold: they permit power for the frame unit electronics to be collected from the busbars ele- ments, and they enable voltage measurements to be made on the busbar elements. More contacts can be provided than is strictly necessary for operation so that there is some redundancy which is useful if contamination prevents any one spring contact from making a good connection with the busbar element. The microprocessor can monitor the state of each spring contact and ad- vise the operator if maintenance of the frame unit is required .

Frame units 11 may also be daisy-chained electrically with power and signaling wires connected from unit to unit using plugs and sockets. Instead of using a plugs-and-socket daisy-chain system to connect frame units, it is also possible to run cable, such as a twisted pair of wires, along the side of each tank and couple power into each frame unit in a non-contact fashion while coupling data again into and out of that cabling in a non-contact fashion. It is also possible to arrange an inductive coupling between frame units. The first frame unit can be powered with hard wiring and the power can then pass wirelessly via the induc ¬ tive couplings down a daisychain of the frame units.

Within the frame units 11 are stabilised power sup ¬ plies which give a suitable accurate voltage output to permit the use of ratiometric Hall effect sensors 10 within the frame unit. The microprocessor 15 within the unit can be programmed with a start-up routine which allows compensation for offset voltages from the Hall effect sensors. The microprocessor 15 can be switched on before fitting the unit 11 to the ER or EW plant to accomplish this.

During assembly, calibration of the Hall effect sen ¬ sors 10 may be carried out to enhance accuracy. This will require the use of a calibration apparatus capa ¬ ble of generating a known set of currents in a suita ¬ ble dummy busbar and hanger bar structure. The micro- processor can thereby acquire and remember a calibra ¬ tion factor for each Hall effect sensor.

Typically a calibrating apparatus will be used to test and calibrate the Hall sensors used in the frame unit. This calibrating unit would typically have a set of hanger bars resting on bus bars in a form which emulates the structure found in the electrolysis cell. Current sources are applied to this rig which are ca- pable of applying a pattern of currents through the various conductors during calibration in a continuous, pulsed or varying manner. In coordination with this current pattern (which is predetermined or conveyed to the microprocessor of the frame unit) measurements are taken by the microprocessor of the Hall effect sensor readings at appropriate moments in time. These read ¬ ings are used to calibrate the current readings pro ¬ duced by the microprocessor. A typical calibration procedure might be as follows. Assuming that all the conductors (or contact points) are surrounded by an array of four Hall effect sen ¬ sors, as previously described. A first test would be to apply a current to one conductor or contact point only. Readings would be taken from the four Hall ef ¬ fect sensors surrounding this conductor or contact point. From these readings a measure of the current in the conductor or contact point would be obtained. Ad ¬ ditionally and simultaneously, readings would be ob- tained from all other Hall effect sensors in the frame unit. This process is then repeated for all conductors or contact points which the frame unit addresses and the currents in which it is responsible for reporting. Hence, when the current in a particular conductor or contact point is being measured, the microprocessor can correct the readings in the array of Hall effect sensors surrounding that array for the effects of any currents which may be flowing in any of the other conductors or contact points. Hence the calibration and learning process which the microprocessor goes through during calibration, forms an essential role in achiev- ing high accuracy current measurements and this meth ¬ odology and associated algorithm is a further aspect of the invention.

From each frame unit 11 current information can be transmitted via the data link to a control room or monitor screen to allow the current measurements to be observed, recorded and analysed. The current data link for each tank may be terminated in a frame unit al ¬ ready employed for returning current information to a control room so that the already established data links may be used for transmission of data from the frame units.

In summary, the present invention provides several ad- vantages. High accuracy of the measurement results from measuring the current in each electrode at a lo ¬ cation where it is concentrated in a point, i.e. at the contact point. The use of a plurality of magnetic field sensors to measure each current permits good signal strength while giving good immunity to unwanted signal intrusion. The inclusion of a microprocessor in unit frames and its ability to remember location with an ID and calibration factors for each Hall effect sensor allows low cost basic Hall sensors to be employed while achieving good accuracy for the unit. The presence of a microprocessor in the unit frame en- ables analysis of the Hall effect sensor signals with ¬ in the frame unit permitting visual signaling to operators to be located on the frame unit. Appropriate de ¬ sign of the frame units permit the units to be in ¬ stalled whilst the ER or EW plant is operating. The frame units allow operation, including raising and lowering of electrodes to proceed unhindered.

While Hall effect sensors and temperature sensors have been disclosed, the frame unit may contain also other sensors or measuring equipment in addition to those described here and its measurement facilities are not limited merely to current and temperature.

While the present inventions have been described in connection with a number of exemplary embodiments, and implementations, the present inventions are not so limited, but rather cover various modifications, and equivalent arrangements, which fall within the purview of prospective claims.