WO2009019333A1 - Plant and process for the electrolytic tinning of steel strips, using an insoluble anode - Google Patents

Abstract

The present invention relates to a plant (1) for the electrolytic tinning of a steel strip (2) travelling continuously in at least one electrodeposition tank (30) containing an acid electrolyte. The plant (1) comprises, in addition, a tin-dissolving reactor (10) and an electrodialysis cell (40), that ensures the recovery of the acid produced in the electrodeposition tank (30). The present invention also relates to an electrolytic tinning process using such a plant (1).

Description

 Installation and method for the electrolytic tinning of steel strips, using an insoluble anode.

The invention generally relates to insoluble anode electrolytic tinning of steel strips, and more particularly to an insoluble anode electrolytic tinning process and the installation for its implementation. The lack of toxicity of tin and the excellent protection against corrosion it brings to steel have long led to the use of tin-plated mild steel in the field of food packaging where it is known under the name of "tinplate". The manufacture of tinplate is generally made from coils ("coils") of mild steel or ultra-soft, which previously undergo a hot rolling operation, followed by a cold rolling operation. At the end of these rolling operations, steel strips of a few tenths of a millimeter thick are obtained. These strips are then annealed, passed after annealing in a cold rolling mill ("skin passed"), degreased, etched and tinned by an electrolytic tinning process (or "electro-tinning"). Tinning is typically followed by finishing operations such as coating remelting, passivation, and oiling.

Electro-tinning is a method of electrodepositing tin on a metal substrate, which consists in establishing the transfer of Sn ²⁺ stannous ions to the band to be coated according to the equilibrium: Sn ²⁺ + 2 e -> Sn deposited

This reaction involves the availability of stannous ions in the bath. In addition to these stannous ions, the bath has an acid for lowering the pH and increasing the electrical conductivity. It also contains additives that contribute, inter alia, to stabilize the stannous ions by preventing them from oxidizing, and to prevent the formation of stannic oxide sludge caused by the oxidation of these stannous ions.

There are two main categories of electro-tinning processes: the first category of processes includes processes using a soluble anode, or so-called "soluble anode" processes, and the second category of processes includes processes implementing a insoluble anode, or so-called "insoluble anode" processes.

The so-called "soluble anode" electro-tinning processes are carried out in electrolytic tinning installations which mainly use high purity tin anodes (ie anodes comprising at least 99.85% by weight of tin), which dissolve during electrolysis and charge the bath with stannous Sn ²⁺ ions.

An example of a "soluble anode" electro-tinning installation known to those skilled in the art is shown in FIG. 1. It is a vertical electro-tinning installation 1, in which a 2 to be coated in a coating tank 3 (or electrodeposition tank) by being wound on two conducting rollers 41, 42 and a bottom roller 5, thus forming a downstream strand 21 and a rising strand 22. The two conducting rollers 41, 42 feed the strip 2 with electrical current. The tin soluble anodes 61, 62 are disposed on either side of the falling 21 and up 22 strands of the steel strip 2 to be coated. This steel strip 2 is connected to the negative pole (represented by the symbol "-" in FIG. 1) of an electric current generator (not shown in FIG. 1), and the soluble anodes 61, 62 are connected to the positive pole (represented by the symbol "+" in Figure 1) of this generator, thus constituting the anode. The anodes 61, 62 and the descending 21 and up 22 strands of the steel strip 2 are partially immersed in an electrolyte solution 7 (or electrolyte). There are several methods of electro-tinning "soluble anode", which differ from each other depending on the electrolyte used. However, in all "soluble anode" electro-tinning processes, the electrolytic coating of tin of the steel strip 2 takes place according to the following reactions:

¹ at the cathode: SnA ₂ + 2e ^" -> Sn + 2A ^~ " at the anode: Sn + 2A ^~ - ^ SnA ₂ + 2e ^"

In so-called "insoluble anode" electro-tinning processes, the tin anode is replaced by an insoluble anode, for example a titanium anode with a coating of a metal (for example a metal of the platinum) or a metal oxide. In this type of process, the tin ions necessary for the coating are, in this case, derived from the electrolyte bath itself in the form of a compound of formula SnA ₂ , A being an acid radical. The reactions taking place at the anode and at the cathode are obviously different: ¹ at the cathode: SnA ₂ + 2e ^" -> Sn + 2A ^" "at the anode: H ₂ O -" ^ O ₂ + 2H ⁺ + 2e ^"

The so-called "insoluble anode" electro-tinning processes are therefore different from those called "soluble anode" in that they lead to the formation of acid in the electrolytic bath correlatively to its depletion tin. These continuous changes therefore require regeneration, the bath also continues. Those skilled in the art are aware of "insoluble anode" electro-tinning processes in which part of the electrolyte is recirculated for the continuous regeneration of the electrolytic bath. Thus, for example, US Pat. No. 4,181,580 describes an electro-tinning installation illustrated in FIG. 2, which implements non-soluble anodes 61, 62, a recirculation circuit 8 for the electrolyte 7, and a reactor fluidized bed 9, in which the electrolyte 7, tin granules 91, and a gaseous stream 92 rich in oxygen are introduced. However, this method has the disadvantage of inducing the formation of quadrivalent tin ions according to the reactions:

Sn + O ₂ + 4H ⁺ -> Sn ⁴⁺ + 2H ₂ O 2Sn ²⁺ + O ₂ + 4H ⁺ - * 2Sn ⁴⁺ + 2H ₂ O These slightly soluble Sn ⁴⁺ ions precipitate in the form of sludge need to be regularly recovered, which greatly reduces the interest of such a process.

In addition, US Pat. No. 5,312,539 proposes another "insoluble anode" tinning process, which uses an anionic membrane dialysis cell and a separate tin dissolution unit in which tin is supplied as an oxide directly dissolved in the acid, or as a tin anode, which is dissolved electrolytically. Such a method has certain disadvantages, and in particular the cost of tin oxide and the need to create a strong concentration gradient across the membrane, which requires the implementation of a concentration unit. On the other hand, even with a strong concentration gradient, the necessary membrane surface (of the order of several thousand m ² for continuous tinning installations of steel strips) makes the industrial application very problematic. . A variant of this process is proposed by Japanese Patent Application JP 51-71499 which groups together the functions of dissolving tin and dialysis in the same tank equipped with two anionic membranes. The installation is less complex than that of US Pat. No. 5,314,539, and does not solve the problems of membrane surface or concentration gradient.

The subject of the present invention is therefore a method of electro-tinning and an installation for its implementation which remedy the drawbacks of the prior art, by the use of a specific electrodialysis cell, connected to the electroplating tray. on the one hand and the dissolution reactor on the other. More particularly, the present invention relates to an installation for the electrolytic tinning of a continuously moving steel strip in at least one plating tank filled with an electrolytic solution which comprises an acid AH and Sn stannous ions ²⁺ in the form of a compound SnA ₂ with A denoting an acid anion, said electrodeposition tank comprising an insoluble anode immersed in the solution electrolytic chamber of the electroplating tank and a cathode formed by the web in continuous flow in the electrolytic solution of the electroplating tank, said apparatus further comprising a tin dissolution reactor which comprises an insoluble cathode and at least one anode of soluble tin, and an electrodialysis cell, characterized in that the electrodialysis cell is an electrodialysis cell comprising a cathode compartment incorporating an insoluble cathode, an anode compartment incorporating an insoluble anode, at least two donor compartments. acid and at least two acid receiving compartments, a first acid receiving compartment being adjacent to the anode compartment separated therefrom by an electrolysis membrane or cationic electrodialysis separation, a first acid donor compartment being adjacent to the cathodic compartment by being separated by another membrane of electr or a cationic electrodialysis separator, wherein a second acid - donor compartment is adjacent to the first acid - receiving compartment separated therefrom by an anionic electrodialysis or electrolysis membrane, and a second acid - receiving compartment is adjacent, on the one hand, to the second acid donor compartment by being separated therefrom by a cationic electrodialysis or selective electrolysis membrane and, on the other hand, to the first or third acid donor compartment separated therefrom; an electrodialysis or selective electrolysis membrane, in the tin dissolution reactor, the tin anode and the insoluble cathode are separated by an anionic electrodialysis membrane defining a cathode zone integrating the cathode and an anode zone integrating the tin anode, a first circuit recirculating the electrolytic solution connects the electroplating tank (30) and the anodic zone of the tin dissolution reactor, - a second recirculation circuit of the electrolytic solution connects the acid donor compartments of the electrodialysis cell and the electroplating tank, and a third electrolytic solution recirculation circuit connects the acid receiving compartments of the electrodialysis cell and the cathodic zone of the tin dissolution reactor.

For the purposes of the present invention, cationic electrodialysis membrane is understood to mean a membrane permeable to cations and which is typically used in an electrodialysis process.

For the purposes of the present invention, cationic electrolysis membrane is understood to mean a membrane permeable to cations typically used in a membrane electrolysis process, but which can advantageously be used in the electrodialysis process according to the invention. because of its robustness and ability to withstand higher current densities than a cationic electrodialysis membrane. For the purposes of the present invention, a cationic electrodialysis membrane for separation electrolysis is understood to mean a membrane which is not permeable. anions and is able to withstand high current densities.

For the purposes of the present invention, a cationic membrane for electrodialysis or selective electrolysis is intended to mean a membrane which is not permeable to anions and which retains, for the most part, the cations

Sn ²⁺ .

For the purposes of the present invention, an anionic membrane for electrolytic electrodialysis is understood to mean a membrane which is permeable to anions.

Compared with a tinning installation incorporating a conventional dialysis cell, such as that of US Pat. No. 5,312,539, the electrodialysis cell of the installation according to the invention makes it possible to considerably reduce the membrane surface required and to overcome a concentration gradient between the compartments. On the other hand, the amount of acid to be recovered can be more easily and quickly controlled by acting on the electrodialysis current.

Moreover, the presence of an anionic electrodialysis or electrolysis membrane in the dissolving reactor between the soluble anode of tin and the insoluble cathode allows the ions A ^" to pass through this membrane from the cathode zone to the cathode. the anodic zone, while the Sn ²⁺ ions produced at the anode remain totally in the anode zone of the reactor, the electrolytic solution contained therein is then recharged with stannous ions, and can then be directed back to the coating.

Advantageously, the first and second recirculation circuits of the electrolytic solution comprise a common oxygen degassing tank, which is arranged upstream of the dissolution reactor in the direction of circulation of the electrolyte in this recirculation circuit. This degassing tank makes it possible to eliminate the gaseous oxygen formed at the insoluble anode of the coating tank.

The acid AH is advantageously chosen from sulphonic acids.

As sulphonic acids that can be used according to the present invention, mention may be made especially of methanesulfonic acid and phenol-sulphonic acid.

The preferred sulfonic acid is methane sulfonic acid.

If a sulphonic acid, and in particular an acid selected from among methanesulfonic acid and phenol-sulphonic acid, is used, the SnA ₂ compound will thus advantageously be a tin sulphonate corresponding to the preferred sulphonic acids according to US Pat. invention: tin phenol sulphonate or tin methane sulphonate. The present invention also relates to a process for the electrolytic tinning of a continuous strip of steel in at least one plating tank filled with an electrolytic solution which comprises an acid AH and stannous Sn ²⁺ ions under form of a compound SnA ₂ with A denoting an acid anion, said tinning process employing a non-soluble anode and the metal strip constituting a cathode which are immersed in the electrolytic solution and between which a potential difference is applied, the SnA ₂ compound from a tin dissolution reactor, which comprises an insoluble cathode and an anode of tin, between which a potential difference is applied, characterized in that the concentration of acid AH is maintained in the electrolytic solution of the tank by carrying out the following steps: a) the dissolution reactor is equipped with tin an anionic electrodialysis or electrolysis membrane between the tin anode and the insoluble cathode, thus defining a cathode zone integrating the insoluble cathode and an anode zone, integrating the soluble anode of tin; b) an electrodialysis cell is provided comprising a cathode compartment incorporating an insoluble cathode, an anode compartment incorporating an insoluble anode, at least two acid donor compartments and at least two acid receiving compartments, a first receiving compartment of acid being adjacent to the anode compartment by being separated by an electrolysis membrane or cationic electrodialysis separation, a first acid donor compartment being adjacent to the cathode compartment separated therefrom by an electrolysis or electrodialysis membrane a second acid - donor compartment being adjacent to the first acid - receiving compartment separated therefrom by an anionic electrodialysis or selective electrolysis membrane, and a second acid - receiving compartment being adjacent to an part of the second acid donor compartment by being separated by a catio membrane electrodialysis or selective electrolysis, and secondly to the first or third separated by an anionic membrane of electrodialysis or selective electrolysis; c) circulating part of the electrolytic solution of the electroplating tank between the electroplating tank and the anode zone of the tin dissolution reactor; d) circulating another part of the electrolytic solution between the electrodeposition tank and the acid donor compartments of the electrodialysis cell; and e) circulating a portion of the electrolyte solution between the acid receiving compartments of the electrodialysis cell and the cathode zone of the tin dissolution reactor. Other advantageous features of the invention will appear in the following description of certain embodiments given as a simple example and shown in the accompanying drawings:

FIG. 1 is a cross-sectional schematic diagram of an example of a soluble anode electro-tinning installation according to the state of the art,

FIG. 2 is a cross-sectional schematic diagram of an example of an insoluble anode electro-tinning installation according to the state of the art; FIG. 3 is a cross-sectional schematic diagram of an example of FIG. installation of electro-tinning according to the invention,

FIG. 4 represents a schematic block diagram of the electrodialysis cell of the electro-tinning installation shown in FIG. 3, FIG. 5 represents a cross-sectional diagram of an example of a dissolution reactor of an electro-tinning installation according to the invention,

FIG. 6 is a view from above of another example of a dissolution reactor of an electro-tinning installation according to the invention.

The electro-tinning (or electrolytic tinning) installation shown in FIG. 1 is a soluble anode electro-tinning installation 1 of the state of the art, which was previously described in the reference to FIG. the prior art which precedes.

The electro-tinning (or electrolytic tinning) installation shown in FIG. 2 is an insoluble anode electro-tinning installation 1 of the state of the art, which was previously described in the reference to FIG. the prior art which precedes.

FIG. 3 shows a schematic diagram of an example installation according to the invention, in which the strip to be coated 20 and an insoluble anode 60 are partially immersed in an electroplating tank 30 (or coating tank). ) containing an electrolytic solution (or electrolyte) containing Sn ²⁺ stannous ions in the form of a SnA ₂ compound and an AH acid, A being an acid anion. The SnA ₂ compound comes from a tin dissolution reactor 10, which comprises an insoluble cathode 120 and a soluble tin anode 160, which are immersed in a tank 130 also containing the same electrolytic solution as the coating tank 30. An anionic electrodialysis or electrolysis membrane 140 is disposed between the electrodes 120, 160 of the reactor 10, so that the reservoir 130 of the reactor 10 is divided into a zone cathode 1200 containing the insoluble cathode 120 and anode zone 1600 containing the soluble anode 160.

In the embodiment of the tinning installation 1 according to the invention shown in FIG. 3, the anode 160 of the reactor 10 is constituted by pellets of tin 161 contained in a basket 162 (called

"Tin dissolving basket"). This basket 162 filled with granules 161 is connected to the positive pole (represented by the symbol "+" in FIG. 3) of a source of electric current (not represented in FIG. 3), the tin aggregates 161 playing the role soluble anode. The insoluble cathode 120 of the tin dissolution reactor

10 is connected to the negative pole (represented by the symbol

"-" in Figure 3) of the same power source.

As a soluble anode 160, it is also possible to use, in the tin dissolution reactor 10 of the plant according to the invention, an anode in massive form (not shown). Furthermore, the electro-tinning installation shown in FIG. 3 comprises, in addition to the coating tank 30 and the tin dissolution reactor 10, at least one electrodialysis cell 40 comprising: a cathode compartment 4200 integrating a insoluble cathode 420, an anode compartment 4600 incorporating an insoluble anode 460, a plurality of acid donor compartments 4400, a plurality of acid recipient compartments 4500, two cationic electrodialysis membranes 470 separated, one being disposed between the cathode compartment 4200 and the acid donor compartment 4400 immediately adjacent thereto, and the other being disposed between the anode compartment 4600 and the receiver compartment d 4500 acid immediately adjacent thereto, a plurality of anionic electrodialysis or electrolysis membranes 450 and a plurality of selective cationic electrodialysis or electrodialysis membranes 440, which are arranged alternately to share the the space between the two membranes 470 in alternating acid-donor compartments 4400 and acid-receiving compartments 4500. FIG. 3 shows that the electroplating tank 30 and the anode zone 1600 of the tin dissolution reactor 10 are connected by a first circuit 200 for recirculating the electrolyte. The electrodeposition tank 30 is also part of a second recirculation circuit 300 of the electrolyte, which connects it to the plurality of acid donor compartments 4400 of the electrodialysis cell 40, while the plurality of receiver compartments. acid 4500 of the electrodialysis cell 40 are part of a third recirculation circuit 400 of the electrolyte. In addition, cathode compartments 4200 and anodic 4600 may be part of a fourth closed loop circulation circuit of an acidic solution, for example sulfuric acid (not shown in FIG. 3). The electro-tinning installation shown in FIG. 3 further comprises an oxygen degassing tank 210 and a hydrogen degassing tank 410. This oxygen degassing tank 210, which here is for example common to the first and second circuits 200 and 300, is disposed downstream of the tank 30 in the direction of flow of the electrolytic solution in these circuits 200, 300, or in other words, upstream of the reactor 10 in the first circuit 200 and upstream of the electrodialysis cell 40 in the second circuit 300. Furthermore, the hydrogen degassing tank 410 is part of the third circuit 400 connecting the cathode zone 1200 of the dissolution reactor 10 to the plurality of compartments Acid receivers 4500 of the electrodialysis cell 40, the hydrogen degassing tank 410 being disposed upstream of the electrodialysis cell 40 in the direction of circulation of the electrolyte in the third circuit 400. , when a potential difference is applied between the electrodes 20, 60 immersed in the coating tank 30, the Sn ²⁺ stannous ions present in the electrolyte in the form of SnA ₂ compound are deposited on the strip to be coated according to the reaction :

SnA ₂ + 2e ^" -" Sn + 2A ^~ The following reaction is observed in parallel with the anode:

2H ₂ O -> O ₂ + 4H ⁺ + 4 th ^"

An electrolyte depleted of stannous ions is thus obtained, part of which is taken from the coating tank 30, and is then subjected to degassing of the oxygen gas in the degassing tank 210 before being introduced into the anode zone 1600 of the reactor dissolution 10 on the one hand, and in the plurality of acid donor compartments 4400 on the other hand.

As in the coating tank 30, a potential difference is applied simultaneously between the electrodes 420, 460 of the electrodialysis cell.

40. The electrolyte from the coating tank 30 is introduced into the plurality of acid donor compartments 4400 delimited by a cationic membrane and an anionic membrane. The Sn ²⁺ ions of the electrolyte remain predominantly in the acid donor compartments while the acidic anions A ^~ migrate to the acid recipient compartments 4500 through the anionic membranes and the H + ions migrate to the recipient compartments. 4500 acid through cationic membranes.

As a selective cationic membrane 440 that can be used according to the invention, the membrane marketed by the company TOKUYAMA SODA under the name CMX-S is recommended. As a cationic separation membrane 470 that can be used according to the invention, the membrane marketed by the company TOKUYAMA SODA under the name C66 is recommended.

Cationic membrane 440 has a selective permeability which permits the transfer of H ⁺ ions to the adjacent acid-receiving compartment and the retention of the majority of Sn ²⁺ ions in the acid-donor compartment as shown in Figure 4.

Moreover, as in the coating tank 30 and in the electrodialysis cell 40, a potential difference is applied simultaneously between the electrodes 120, 160 of the tin dissolution reactor. 10, which leads to the electrolytic dissolution of the soluble anode 160 of tin according to the reaction:

Sn + 2A ^~ -> SnA ₂ + 2e ^"

In parallel, the following is observed at the cathode of the reactor 10:

2AH + 2e ^" -> H ₂ + 2A ^~

The electrolytic dissolution of the tin granules 161 ensures the production of Sn ²⁺ stannous ions, which thanks to the impermeability of the Anionic membrane 140 remain largely in the vicinity of the anode.

The A- ions which are released at the cathode of the reactor 10 pass from the cathode zone 1200 to the anode zone 1600 through the anionic membrane.

The electrolyte of the anodic zone 1600 of the reactor 10 thus recharged with stannous ions can then be recovered and directed back to the coating tank. The electrolyte contained in the cathode zone 1200 of the reactor 10 is directed by the recirculation circuit 400 to the hydrogen degassing tank 410 and is introduced into the plurality of acid recipient compartments 4500 of the electrodialysis cell 40. .

The electrodialysis cell 40 makes it possible to recover the excess electrolyte acid produced in the coating tank 30. The number of donor and acid recipient compartments and therefore the total membrane area required is a function of the amount of acid to be used. recover and applied current density.

FIG. 5 shows an example of a dissolution reactor 10 according to the invention, comprising a tank 130 of cylindrical shape filled with electrolyte, and separated in two by an anionic electrodialysis membrane 140, also of a shape cylindrical, thus defining a central anode zone 1600 comprising the soluble anode 160, and an external cathode zone 1200 comprising the cathode 120.

The cylindrical shape of the reservoir 130 and the cationic membrane 140 is given here by way of example. But, the reservoir 130 and the cationic membrane 140 may also be of parallelepipedal shape.

The cathode 120 is connected to the negative pole of a source of electric current (represented by the symbol "-" in FIG. 5) and the anode 160 is connected, in its upper part, to the positive pole (represented by the symbol " + "In Figure 5) of the same source of electric current.

FIG. 5 shows that the soluble anode of tin 160 comprises a dissolution basket 162 comprising tin granules 161. This basket 162 is divided into three distinct superimposed parts: a lower zone 1621 immersed in the electrolyte contained in the tank 130; a middle zone 1622 for recovering the electrolyte, which is situated above the lower zone 1621 by being contiguous thereto and which is not immersed in the electrolyte contained in the reservoir 130, but which is wetted by the electrolytic solution when circulated in circuit 200, and an upper dry zone 1623 for supplying dry tin granules 161 and transmitting electrical dissolution current. The lower 1621 and middle 1622 areas of the dissolution basket 162 of the anode 160 are both made of non-electrically conductive material. As an electrically nonconductive material usable according to the invention for producing the lower zones 1621 and median 1622 of the basket 162 of the soluble anode 160, plastics, and composites such as the polyester resins and the polyesters, are recommended. polymers coated steels.

On the other hand, the upper region 1623 for supplying tin granules 161 is made of an electrically conductive material. As an electrically conductive material that can be used according to the invention to produce the basket 162 of the soluble anode 160, mention may notably be made of stainless steel.

The lower zone 1621 immersed in the electrolyte comprises a mesh 163 comprising a mesh plastic mesh adapted to the retention of the tin granules, between 0.05 and 0.50 mm, and preferably between

0.1 and 0.30 mm. This net is supported by the basket envelope which has electrolyte contacting openings which are at least 50 times wider than the mesh of the net. Openings (dashed in FIG. envelope of the basket

162.

The median zone 1622 includes a recovery trough 164 of the regenerated electrolyte, this trough being supplied via a trellis 165

(identical to that 163 of the lower zone 1621) and openings (in dashed lines in FIG. 5) formed in the envelope of the basket 162 (identical to those of the lower zone 1621).

The upper zone 1623 comprises a filling hopper 166 in tin granules 161, which is connected to the positive pole of the power supply.

The lower zone 1621 of the basket 162, which is immersed in the electrolyte, is surrounded by a cationic membrane 140 of circular shape. This cationic membrane 140 is advantageously supported by at least one plastic net, which makes it possible to ensure the rigidity of the membrane 140.

The electrolyte to be treated is introduced into the lower zone 1621 of the basket by intake ducts.

201 at a pressure sufficient to allow its overflow in the recovery trough 164 of the median zone 1622. During the course of the tin granules

161 through the basket 162, the electric current ensures the dissolution of said granules 161 and the acid is charged with Sn ⁺⁺ ions which remain close to the anode 160.

The electrolyte thus recharged with tin is recovered at the trough 164, before being returned to the coating tank 30 via the return lines 202.

FIG. 6 shows, in plan view, another example of a dissolution reactor 10 according to the invention, which comprises a plurality of soluble anodes 160, each having a basket 162 filled with tin granules 161, each basket 162 being surrounded by an anionic membrane 140 circular.

A feed device 400 in granules 161 serves hoppers 166 of all baskets 162 of the dissolution reactor 10. This device 400 may be a treadmill or vibrating, or non-electrically conductive pipes. The device 400 acts intermittently as a function of a signal given by a device for detecting the level of granules in the hoppers 166, so as to maintain a constant level of granules 161 in the basket 162.

Claims

1. Installation (1) for the electrolytic tinning of a strip of steel (2) continuously moving in at least one plating tank (30) filled with an electrolytic solution which comprises an acid AH and stannous ions Sn ²⁺ in the form of a compound SnA ₂ with A denoting an acid anion, said plating tank

(30) comprising at least one insoluble anode (60) immersed in the electrolytic solution of the electroplating tank (30) and a cathode (20) constituted by the continuous strip (2) in the electrolytic solution of the plating tank. (30), said plant (1) further comprising at least one tin dissolution reactor (10) which comprises an insoluble cathode (120) and at least one soluble tin anode

(160), and an electrodialysis cell (40) characterized in that:

the electrodialysis cell (40) is an electrodialysis cell comprising a cathode compartment

(4200) incorporating an insoluble cathode (420), an anode compartment (4600) incorporating an insoluble anode (4600), at least two acid donor compartments (4400) and at least two acid recipient compartments (4500), a first acid receiver compartment

(4500) being adjacent to the anode compartment (4600) separated therefrom by an electrolysis membrane or cationic separation electrodialysis (470), a first acid donor compartment (4400) being adjacent to the cathode compartment (4200) by being separated by an electrolysis membrane or cationic separation electrodialysis (470), a second compartment acid donor (4400) being adjacent to the first acid receiving compartment (4500) separated therefrom by an anionic electrodialysis or electrolysis membrane (450), and a second acid receiving compartment (4500) being adjacent firstly to the second acid - donor compartment (4400) separated therefrom by a cationic electrodialysis or selective electrolysis membrane (440), and secondly to the first or third donor compartment; acid (4400) separated therefrom by an anodic electrodialysis or electrolysis membrane (450), in the tin dissolution reactor (10), the tin anode (160) and the insoluble cathode (120). ) are separated by an anionic electrodialysis or electrolysis membrane (140) defining a cathode zone (1200) integrating the cathode (120) and an anode zone (1600) incorporating the tin anode (160), a first recirculation circuit (200) of the electrolytic solution connects the tank of electrode (30) and the anode zone (1600) of the tin dissolution reactor (10), a second recirculation circuit (300) of the electrolytic solution connects the plurality of dilution acid donor compartments (4400) of the electrodialysis cell and plating tank

(30), and a third recirculation circuit (400) of the electrolytic solution connects the plurality of acid recipient compartments (4500) of the electrodialysis cell (40) and the cathode region (1200) of the dissolution reactor. tin (10).

2. Installation (1) according to claim 1, characterized in that said first (200) and second (300) recirculation circuits of the electrolytic solution comprise an oxygen degassing tank (210) disposed downstream of the tank d electroplating (30) in the flow direction of the electrolytic solution in each of the first (200) and second (300) recirculation circuits.

3. Installation (1) according to claim 1 or 2, characterized in that the third circuit (400) for circulating the electrolytic solution comprises a hydrogen degassing tank (410).

4. Installation (1) according to any one of the preceding claims, characterized in that the soluble tin anode (160) is in the form of tin granules (161) contained in a basket (162).

5. Installation (1) according to claim 4, characterized in that the basket (162) comprises three distinct superimposed parts: - a lower zone (1621) which is immersed in the electrolytic solution contained in the reservoir (130) of the reactor of dissolution (10), a middle zone (1622) for recovering the electrolyte, which is situated above said lower zone (1621) by being contiguous thereto, said median zone (1622) not being immersed in the solution electrolytic solution contained in the reservoir (130) of the dissolution reactor (10), but being wetted by the electrolytic solution when it is circulated in the circuit 200, an upper zone (1623) dries for the supply of granules of tin (161) and the transmission of the dissolution electric current, said upper zone (1623) being located above said median zone (1622) by being contiguous thereto.

6. Installation (1) according to claim 5, characterized in that the lower (1621) and median (1622) areas of the basket (162) are made of a non-electrically conductive material.

7. Installation (1) according to claim 6, characterized in that the electrically nonconductive material of the lower (1621) and median zones

(1622) of the basket (162) is a plastic material or a composite material selected from the group consisting of reinforced polyester resins or polymer coated steels.

8. Installation (1) according to one of claims 5 to 7, characterized in that the upper zone (1623) of the basket (162) is made of an electrically conductive material.

9. Installation (1) according to any one of claims 5 to 8, characterized in that the lower zone (1621) of the basket (162) comprises: a lattice (163) comprising a plastic net whose mesh is between 0.05 mm and 0.5 mm, and an envelope for supporting said lattice (163) and having one or more covers for contacting the granules (161) with the electrolytic solution.

10. Installation (1) according to any one of claims 5 to 10, characterized in that the central region (1622) of the basket (162) comprises: a mesh (165) comprising a plastic net whose mesh is between 0.05 mm and 0.5 mm, and

- a recovery trough (164) of the electrolytic solution, said trough (164) being supplied with electrolytic solution via the trellis (165).

11. Installation (1) according to any one of the preceding claims, characterized in that the dissolution reactor (10) comprises a plurality of soluble anodes (160), each of these anodes (160) having a hopper (166) and being surrounded by an anionic membrane of electrodialysis or electrolysis

(140).

12. Installation (1) according to claim 11, characterized in that it comprises a feeding device (400) in granules which serves intermittently hoppers (166) anodes (160).

13. Installation (1) according to claim 12, characterized in that the feeding device (400) granules (161) is a vibrating or rolling belt, or a set of non-conductive pipes 1 'electricity.

14. A method of electrolytically tinning a continuously moving steel strip (20) in at least one electroplating tank (30) filled with an electrolytic solution which comprises an AH acid and Sn ²⁺ stannous ions. in the form of a SnA ₂ compound with A denoting an acid anion, said tinning process employing at least one insoluble anode (60) and the metal strip (20) constituting a cathode which are immersed in the electrolytic solution and enter which is applied a potential difference, the SnA ₂ compound from a tin dissolution reactor (10), which comprises an insoluble cathode (120) and a tin anode (1602), between which a difference is applied of potential, characterized in that the concentration of acid AH is kept constant in the electrolytic solution of the tank (30) by carrying out the following steps: a) an anionic membrane is placed in the tin dissolution reactor (10) electrodialysis or electrolysis device (140) between the tin anode (160) and the insoluble cathode (120), thereby defining a cathode zone (1200) integrating the insoluble cathode (120) and anode zone (1600) , integrating the soluble anode of tin (160); b) providing an electrodialysis cell (40) comprising a cathode compartment (4200) incorporating an insoluble cathode (420), an anode compartment (4600) incorporating an insoluble anode (4600), at least two acid donor compartments ( 4400) and at least two acid-receiving compartments (4500), a first acid-receiving compartment (4500) being adjacent to the anode compartment (4600) separated therefrom by an electrolysis membrane or cationic separation electrodialysis membrane (470), a first acid donor compartment (4400) being adjacent to the cathode compartment (4200) separated therefrom by an electrolysis membrane or cationic separation electrodialysis (470), a second acid donor compartment (4400) being adjacent to the first acid-receiving compartment (4500) by being separated by an anionic electrodialysis or electrolysis membrane (450), and a second acid receiving compartment (4500) being adjacent on the one hand to the second acid donor compartment (4400) separated therefrom by a cationic electrodialysis or selective electrolysis membrane (440), and on the other hand to first or third acid donor compartment (4400) separated therefrom by an anionic membrane for electrodialysis or electrolysis

(450); c) circulating a portion of the electrolytic solution between the electrodeposition tank (30) and the anode zone (1600) of the tin dissolution reactor (10); d) circulating another portion of the electrolytic solution between the electroplating tank (30) and the acid donor compartments (4400) of the electrodialysis cell (40); and e) circulating a portion of the electrolyte solution between the acid receiving compartments (4500) of the electrodialysis cell (40) and the cathode zone (1200) of the tin dissolution reactor (10).

15. Method according to claim 14, characterized in that the electrolytic solution taken from the coating tank (30) is subjected to degassing of the oxygen before being injected into the anode zone (1600) of the dissolution reactor. (10), or in the acid donor compartments (4400) of the electrodialysis cell (40).

16. The method of claim 14 or 15, characterized in that the electrolytic solution taken from the cathode zone (1200) of the dissolution reactor (10) is subjected to a degassing of hydrogen, before to be injected into the acid recipient compartments (4500) of the electrodialysis cell (40).