EP0485354A1 - Process and apparatus for controlling the thickness of an electroplated coating on a metallic plate or foil - Google Patents

Abstract

Process and apparatus for controlling the thickness of a coating deposited electrolytically in an electrolysis bath (14) on at least one face (1, 2) of a metal plate or sheet (3) forming a cathode and travelling in a specified direction between at least two anodes (5, 6) each having a surface (7, 8) which lies at a substantially uniform distance from the plate (3), the surface of an anode situated on one side of the plate (3) being at least partially opposite the surface of an anode situated on the other side, the anodes (5, 6) being substantially at the same potential and the active surface area of the surface (7, 8) of at least one anode on the side of the face in question of the plate (3) being controlled in the specified direction as a function of the desired thickness. <IMAGE>

Description

The present invention relates to a method for adjusting the thickness of a coating deposited by electrolysis in an electrolytic bath on at least one of the faces of a metal plate or sheet forming a cathode and running in a predetermined direction between at least two anodes having each a surface which extends, both in the determined direction and transversely thereto, at a substantially constant distance from the metal plate or sheet, the surface of an anode situated on one side of the metal plate or sheet being at least partially in opposition to the surface of an anode located on the other side.

BE-B-901.001 discloses a device of the same kind in which the adjustment of the coating thickness deposited on one face of the metal plate or sheet relative to that deposited on the other face of the latter can be performed, for a given speed of movement of the metal plate or sheet, by modifying the anode potential on the side of the face to be adjusted relative to the anode potential on the side of the other face.

In the known device, the metal plate or sheet to be coated is usually narrower transversely to the direction of travel than the anodes, so that during a transverse movement relative to said direction, or during a variation in width, the metal plate or sheet remains completely between the anodes. The transverse ends of the surfaces of anodes which are in opposition and which are not separated by the metal plate or sheet face each other directly and the difference in potential prevailing between these anodes in opposition generates between said surfaces lines of current which cause a deposit unwanted electrolytic coating on the least positive anode. This undesirable deposit can, among other things, adversely affect the coating thickness of the face of a metal plate or sheet which can subsequently pass in front of this deposit, deteriorate the anode, unnecessarily consume deposit metal and electrical energy, etc.

GB-A-2 093 863 discloses, inter alia, "edge masks" which consist of an electrically non-conductive material and which are arranged along the two longitudinal edges of the metal plate or sheet to be coated in order to cut the current lines outside this metal plate or sheet between the opposing anodes. However, these edge masks have the drawback, on the one hand, of having to be profiled in a manner adapted to the longitudinal edges of the metal plate or sheet and, on the other hand, of having to constantly follow the transverse displacements of these edges resulting from transverse displacements of said plate or metal sheet or from variations in width thereof. To constantly monitor the movements of the aforementioned edges, it is necessary to use very precise and very complicated automatic devices, therefore very expensive and fragile.

The object of the invention is to remedy these drawbacks and to present a method which makes it possible, on the one hand, to avoid coating deposits on the anodes themselves and, on the other hand, to carry out a simple adjustment and precise coating thickness on one side regardless of the coating thickness setting on the other side, while leaving the anodes free and unobstructed transversely to the determined direction so that they can act fully on the metal plate or sheet even if it has a transverse displacement, variations in width, irregular longitudinal edges, etc.

To this end, according to the method of the invention, the anodes are maintained on either side of the metal plate or sheet at substantially the same potential and the active surface area of the surface is adjusted in the determined direction an anode on the side of the concerned face of metal plate or sheet as a function of the desired coating thickness.

According to another embodiment of the invention, said active area is adjusted so that the total active length of anode in the determined direction is constant perpendicularly to this direction of travel.

According to an advantageous embodiment of the invention, to adjust the active area, a screen is placed between the relevant face of metal plate or sheet and the surface of at least one anode opposite this face.

According to a particularly advantageous embodiment of the invention, to adjust the above total active length, at least part of an anode is removed and the part removed is replaced by a non-conductive substitution element, of shape and dimensions substantially identical.

The invention also relates to a device for adjusting the thickness of a coating deposited by electrolysis in an electrolytic bath on at least one of the faces of a metal plate or sheet forming a cathode moving in a determined direction between at least two anodes each having a surface which extends, both in the determined direction and transversely to it, at a substantially constant distance from the metal plate or sheet, the surface of an anode situated on one side of the plate or metal foil being at least partially in opposition to the surface of an anode located on the other side.

According to the invention, this device comprises means for maintaining the anodes on either side of the metal plate or sheet substantially at the same potential and means for adjusting the active area of at least one anode by modifying the length total active anode taken in the determined direction, this modified active length being constant transverse to the determined direction.

Other details and particularities of the invention will emerge from the description of the drawings appended to this specification and which illustrate, by way of non-limiting examples, the method and a particular embodiment of the device according to the invention.
Figure 1 shows schematically in cross section a metal sheet to be coated disposed between two anodes.
FIG. 2 schematically shows a longitudinal section in elevation of an installation implementing the device and the method of the invention.
Figure 3 is an enlarged longitudinal sectional view of part of the installation of Figure 2, according to another embodiment of the invention.
FIG. 4 schematically represents a longitudinal section of another embodiment of the device according to the invention.
FIG. 5 schematically represents an advantageous embodiment of the invention.

The device according to the invention can advantageously be used in installations for coating by electrolysis of the two faces 1,2 (FIG. 1) of a metal plate or sheet 3 forming the cathode and being for example in the form of a strip. steel 3 whose running direction may be horizontal, the steel strip being guided flat to the place of deposition of the electrolytic coating. The steel strip 3 passes for example between respectively upper 5 and lower anodes 6 substantially parallel to the steel strip 3. The anode surfaces 7, 8 are equidistant from the latter and face each other in the absence of the steel strip 3.

It is commonly necessary to coat the two sides with a steel strip, for example nickel, the thickness of which deposited on side 1 may have to be 2 μm while that deposited on side 2 may only be 1 µm.

An electrolytic coating installation known by BE-B-901.001, under the name of "Flash" cell is shown diagrammatically in FIG. 2 by way of example and supplemented by the device for adjusting the coating thickness according to a form of realization of the invention.

According to FIG. 2, a steel strip 3, for example, is brought in a direction of travel 10, by means of guide rollers 11, against a conductive roller 12 equipped with known means for transmitting to the steel strip 3 cathodic potential. The steel strip 3 guided longitudinally by two pairs of upper and lower guide rollers 13 travels horizontally and enters through an opening 16 in a known enclosure 15 comprising an electrolytic bath 14 and emerges therefrom through an opening 17. Then, the steel strip 3 can come into contact with another conductive roller 12 against which it is pressed by a roller 18 and from which it departs while being deflected on the guide roller 19 by the support roller 20.

The enclosure 15 comprises upper anodes 5 above the steel strip 3 and lower anodes 6 below this strip 3. These anodes 5, 6 advantageously have the shape of a rectangular parallelepiped whose large faces are parallel to the steel strip 3 and extend longitudinally perpendicular to the direction of travel of the strip 3. Between two anodes 5 or 6 on the same side of the steel strip 3 is provided each time for example a slot introduction 21 of electrolytic liquid to constantly supply the electrolytic bath 14, this liquid escaping through the aforementioned inlet 16 and outlet 17 openings. Known injectors 22, 23 are supplied in a known manner with electrolytic liquid from a box 24 which collects the liquid flowing inter alia through the openings 16 and 17, and bring this liquid to the aforesaid slots. In addition, an upper anode 5 is, opposite a lower anode 6.

According to the invention, in the installation of FIG. 2 for example, to avoid untimely deposits on the anodes 5, 6, these are set to the same anode potential by the electrical conductors 105, 106 so that 'no current line appears between the upper anodes 5 and the lower anodes 6 at the places where the steel strip 3 does not separate these upper 5 and lower anodes 6. The potential difference between the anodes and the cathode, c that is to say the steel strip 3, is given for example by a current source 108 connected in a known manner, on the one hand, to the electrical conductors 105, 106 and, on the other hand, by electrical conductors 109, to the conductive rollers 12. This potential difference is chosen by a person skilled in the art so that current lines generated between this metal strip or sheet 3 and the anodes deposit, for example nickel, on the faces 1, 2 of it during its parade lying in the electrolytic bath 14.

For identical anode surfaces on either side of the steel strip 3 and for a given running speed of this strip in the enclosure 15, the duration of exposure of each face 1 and 2 thereof to current lines is the same. To adjust the coating thickness of the face 1 relative to that of the face 2, according to the invention, for example, a part of the surface of the lower anodes 6 is masked opposite the face 2, so as to thus modify this exposure time. This masking is advantageously carried out by means of a material which does not conduct electricity, which prevents current lines from being generated where the masking is carried out. This non-electrically conductive material can for example be polypropylene, polyvinyl chloride, polyphenylene sulfide, teflon, etc. which are resistant to electrolytes. This leaves an "active anode surface" free.

In the context of the present description, the term "active anode surface" should be understood to mean the total surface of the anode (s) 5, 6 exposed directly to the cathode at a minimum distance from the latter making it possible to create a maximum acceptable density of electrolysis current, the surface exposed directly to the cathode being that from which the current lines leave towards the cathode. The active anode surface is a function, among other things, of the thickness of the coating to be deposited, and is advantageously produced so that, transversely to the direction of travel, the released length of anode or total active length of anode traversed by n ' any point on the steel strip 3 in the direction of travel is the same, and therefore the duration of exposure to the current lines is also the same for any point on this face 2.

As shown in FIGS. 2 and 3, the above-mentioned masking can be obtained by means of a screen 26 which is not electrically conductive, arranged between an anode 6 to be put out of service and the steel strip 3, this screen 26 can advantageously be fixed in a known manner at the respective anode 6. The area of the screen is substantially the same as that of the anode surface 8 to be masked or possibly the dimension of the screen 26 in the direction of travel is equal to the corresponding dimension of the anode 6 and the dimension transverse of the screen 26 in this direction is at least equal to the transverse dimension of the steel strip 3 in order to block said streamlines, including at the location of the longitudinal edges of the steel strip 3.

In this FIG. 3, a similar screen 26a has also been shown offset in the direction of travel relative to the anode 6a so as to cover only part of the corresponding anode surface 8. To this end, known adjustment means can be used to allow for example to move the screen 26a between a position where it completely covers the anode surface 8 and a position completely withdrawn to the left in the direction of travel, at away from this anode surface 8, in order to possibly select an appropriate partial overlap of the anode 6.

It is also possible, according to the invention, to use screens 26b whose dimension in the direction of travel is less than the corresponding dimension of the anode 6.

Thus, by using one or more screens 26 and / or a screen 26a with an adjustable position and / or partial screens 26b, it is possible to obtain a precise adjustment of the above active length of the anodes corresponding to a face 1, 2 for which the coating thickness according to the invention is to be adjusted.

In another embodiment, also illustrated in FIG. 3, the screen according to the invention can consist of a curtain 27, the dimension of which is transverse to the direction of travel can be equal to the corresponding dimension of the anodes 6, while that the dimension of this curtain 27 in the direction of travel can be sufficient to cover all the anodes 6 arranged on the same side of the steel strip 3. It is possible, for example, to wind the curtain 27 around a drum 28 of a known type, arranged outside the enclosure 15, the curtain passing inside the enclosure 15 through an appropriate horizontal slot 29, the drum 28 serving to store all or part of the curtain 27 not used to mask the anode surface 8. The curtain 27 which has just been described as well as the screens 26, when they cover several anodes, can be perforated so that the electrolytic liquid introduced by the slots between anodes can pass between the curtain 27 or the screen 26 and the steel strip 3 to be coated, while respecting, by an appropriate arrangement of openings, the condition of achieving a total active length of anode in the direction of constant travel transversely to the direction of travel.

It is clear that the explanations given regarding screens 26 or curtains 27 adjoining the lower anodes 6 are valid for the upper anodes 5 and for any other form of anode used for this type of coating in electrolytic installations.

The present invention also provides that, in order to reduce the thickness of coating deposited for example on face 2 with respect to that deposited on face 1, one or more anodes 5, 6 are removable and can be replaced by substitution elements 30 (Figure 3) non-electrically conductive or part of which is non-conductive so as to meet the condition of total active length of constant anode for any point on face 1, 2 of steel strip 3 to be coated in progress scroll. These substitution elements 30 have for example a volume practically identical to that of the anodes so that, for example, the flow of the electrolytic liquid in the enclosure 15 and through the slots 21 provided between two neighboring anodes remains substantially unchanged, the fasteners removable from these removable anodes and from these removable substitution elements 30 being further known.

Another embodiment of the adjustment of the anode surface to obtain an active surface according to the invention is shown diagrammatically in FIG. 4. In this case, the anode 6 is constituted for example by a metallic strip 31 of which a section or strand 32 having the above active area is stretched horizontally, parallel to the metal sheet or plate 3, between a spacer 34 for fixing to the side walls not shown of the enclosure 15 and a deflection roller 35 around which the inactive strand 36 constituting the anode section 136 not used but available is wound on a half-turn to then extend substantially parallel to the strand 32, on the other side of the latter relative to the sheet or metal plate 3 to be coated, known means supporting the deflection roller 35 to allow the adjustment of its position in the direction of travel, for example parallel to the steel strip 3, and therefore the adjustment of the active area of the strand 32. D other known means serve to tension the metallic strip 31, for example by exerting traction on the end 37 of the inactive strand 36.

Another advantageous embodiment of the adjustment of the active area of a metal strip anode 31 according to the invention consists in substantially increasing the distance between the metal plate or sheet 3 and a portion 136 of the strip 31, while the active area the tape is parallel to the metal plate or sheet 3, at a usual distance from electrolysis. This part 136 will be considered inactive, although in some cases it may be the source of a minimum deposit on the cathode. However, by definition, the active anode surface is that of the anode or anodes extending near the cathode. Rollers 39, 40, parallel to each other and to the metal plate or sheet 3, carried by an adjustment carriage known per se 41 advantageously constitute a baffle to adjust the above-mentioned active area in the direction of the double arrow 42. The two ends longitudinal of the ribbon 31 are each fixed to a spacer 34.

The same adjustment methods and devices according to the invention can also be used in other installations or cells for coating by electrolysis, as for example in those where the electrolytic liquid is injected against the current of the running of the steel strip. 3, whether the anodes 5, 6 are respectively separated by slots for supplying electrolytic liquid or not.

EXAMPLE

In the case of an installation or cell of the "Flash" type already mentioned, four anodes 5, 6 were placed opposite each face 1, 2 to be coated, 10 mm from the corresponding face, transversely to the direction of travel of the steel strip 3. Each anode 5, 6 had an anode surface 7, 8 of 1000 mm x 250 mm, parallel to said strip. Two anodes 5 or 6 on the same side of the steel strip were separated by a slot 21 of about 10 mm. The total active anode length obtained for each face was therefore 1000 mm (4 x 250 mm).

These 5.6 anodes were made of lead and silver alloy (1%), of titanium coated with ruthenium oxide or iridium oxide (insoluble anodes) or in the same metal as that to be deposited on the steel strip 3 to be coated (soluble anodes).

The metal to be deposited being nickel, the electrolyte had the following composition:
[NiSO₄] = 232 g / l
[H₂SO₄] = 10 g / l
[H₃BO₃] = 50 g / l

The electrolyte was injected through the slots 21 with a total flow of 150 m³ / h per side to be coated.

• mettre en série deux cellules "Flash" semblables traitant chacune les deux faces 1, 2 ;
• choisir une température d'électrolyse de 70°C ;
• régler la vitesse de défilement de la bande d'acier 3 à 40 m/min. ;
• régler le courant par face et par cellule à 11,5 kA, la densité de courant étant ainsi de 230 A/dm².

To obtain a nickel deposit of 2 μm on the two faces of a steel strip 500 mm wide, the following conditions were achieved:

• put in series two similar "Flash" cells each treating the two faces 1, 2;
• choose an electrolysis temperature of 70 ° C;
• adjust the running speed of the steel strip 3 to 40 m / min. ;
• set the current per side and per cell to 11.5 kA, the current density thus being 230 A / dm².

To make a deposit of 2 μm on face 1 and of 1 μm on face 2, according to the invention, a masking screen has been inserted between face 2 of the metal strip 3 and two corresponding anodes 6. In this way, this face 2 only underwent an exposure reduced to half the exposure of the face 1 subjected to the four anodes 5. This masking screen was made up of two rigid polypropylene plates of 2 mm d 'thickness each covering the anode surface of an anode 6. These plates thus arranged, however, allowed normal flow of electrolytic liquid through the slots 21 above.

According to the invention, each cell received a total current of 17.25 kA distributed between the anodes 5 and 6.

According to the prior art, to realize a deposit of 2 µm on side 1 and 1 µm on side 2, for example it was necessary to maintain the current of 11.5 kA per cell for the anodes 5 of side 1 and reduce the current to 5.75 kA for the anodes 6 of the face 2. This resulted in a potential difference between the anodes 5 and the anodes 6 and therefore a deposit of nickel on the less positive anodes 6 in the places not masked by the steel strip 3, ie in the case of the example, over 250 mm on either side of the area masked by the steel strip 3 when the latter was correctly aligned in the cell.

It should be understood that the invention is in no way limited to the embodiments described and that many modifications can be made to the latter without departing from the scope of the present invention. This is how the electrolyte can be injected through the opening 17 from which the metal strip exits the cell. The circulation of the electrolyte will therefore be, in this case, against the current with respect to the direction of travel of the steel strip. The steel strip can be brought to cathodic potential by means of a single conductive cylinder disposed upstream or downstream of the electrolysis zone.

Claims (10)

Method for adjusting the thickness of a coating deposited by electrolysis in an electrolytic bath (14) on at least one of the faces (1,2) of a metal plate or sheet (3) forming a cathode and running in a determined direction between at least two anodes (5, 6) each having a surface (7,8) which extends, both in the determined direction and transversely thereto, at a substantially constant distance from the metal plate or sheet (3) , the surface of an anode located on one side of the metal plate or sheet (3) being at least partially in opposition to the surface of an anode located on the other side, characterized in that the anodes are maintained (5, 6) on either side of the metal plate or sheet (3) substantially at the same potential and in that one adjusts, in the determined direction, the active area of the surface (7, 8) d '' at least one anode on the side of the concerned face of plate or meta sheet Depending on the desired coating thickness. Method according to claim 1, characterized in that the said active area is adjusted so that the total active length of the anode in the determined direction is constant transverse to this direction of movement. Method according to either of Claims 1 and 2, characterized in that, to adjust the active area, a screen (26, 26a, 26b, 27) is placed between the face concerned (1, 2) of plate or sheet metal (3) and the surface of at least one anode (5, 6) facing this face. Method according to Claim 3, characterized in that at least one curtain-shaped screen (27) is produced which extends transversely to the determined direction over a width at least equal to the width of the metal plate or sheet (3 ), this curtain (27) being able to be extended in the determined direction between at least part of the anodes (5, 6) and the metal plate or sheet 3. Method according to claim 3, characterized in that a screen (26, 26a) is produced which is substantially of the same size. that the surface (7, 8) of at least one corresponding anode (5, 6) and in that this screen is placed opposite this anode is shifted in the above-mentioned determined direction to cancel or adjust the active surface of the anode. Method according to Claim 2, characterized in that, in order to adjust the above-mentioned total active length, at least one part of the anode (5, 6) is removed and the part removed is replaced by a non-conductive substitution element (30) d electricity of shape and dimensions substantially identical to the deleted part. Device for adjusting the thickness of a coating deposited by electrolysis in an electrolytic bath (14) on at least one of the faces (1, 2) of a metal plate or sheet (3) forming a cathode and moving in a direction determined between at least two anodes (5, 6) each having a surface (7, 8) which extends, both in the determined direction and transversely thereto, at a substantially constant distance from the metal plate or sheet (3 ), the surface of an anode located on one side of the metal plate or sheet being at least partially in opposition to the surface of an anode located on the other side, characterized in that means are provided to maintain the anodes (5, 6) on either side of the metal plate or sheet substantially at the same potential and in that means are provided for adjusting the active area of at least one anode (5, 6) by modifying the total active length of anode taken e along the determined direction, this modified active length being constant transverse to the determined direction. Device according to Claim 7, characterized in that the above-mentioned adjustment means comprise a screen (26, 26a, 26b, 27) which extends transversely to the direction determined over at least the width of the metal plate or sheet (3) , between the latter and at least one anode (5, 6) on the side of the face (1, 2) whose thickness is to be adjusted, and means for adjusting the position of the screen in the determined direction. Device according to claim 8, characterized in that the screen has the form of a movable curtain (27) in the direction of movement of the metal plate or sheet (3) between at least one of the faces (1, 2) of the latter and the anode (5, 6) located on the side of this face. Device according to any one of Claims 7 to 9, characterized in that the anodes (5, 6) on either side of the metal plate or sheet (3) are connected to the same source of electrical energy.

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