BE1018637A3 - PROCESS FOR TREATING ALKALINE AND SALINE BATTERIES FOR THE VALORIZATION OF ZINC AND MANGANESE - Google Patents

Abstract

Process for the treatment of alkaline and saline batteries comprising a mechanical grinding of said batteries to obtain a crushed battery, at least one separation making it possible to isolate the black mass, an acid leaching of the black mass making it possible to obtain a mixed solution of salts of manganese and zinc, a solid / liquid separation making it possible to recover said mixed solution of manganese and zinc salt, a precipitation of zinc in the form of zinc sulphide and a selective recovery of the compounds of manganese and zinc.

Description

"PROCESS FOR TREATING ALKALINE AND SALINE BATTERIES FOR THE VALORIZATION OF ZINC AND MANGANESE"

The present invention relates to a method for treating alkaline and salt batteries comprising the steps of: - mechanical grinding of said batteries to obtain a crushed battery including ferrous metals, non-ferrous metals and a fine fraction called black mass ( BM) containing zinc and manganese compounds, - at least one separation allowing to isolate the black mass, - an acid leaching of the black mass making it possible to obtain a mixed solution of manganese and zinc salts by means of a mineral acid, - a solid / liquid separation for recovering said mixed solution of manganese and zinc salts, and - a selective recovery of the manganese and zinc compounds.

Such a process is known from, for example, EP 620 607. The method of treating used batteries according to EP 620 607 is a method in which used batteries are subjected to mechanical treatment in order to dislocate the battery casings, then to a battery. magnetic sorting for separating the ferrous metals, the fraction freed of ferrous metals being then floated to remove the inert. Then, the dense mineral sludge obtained after flotation is leached by sulfuric acid, pH adjusted to a value between 2.5 and 4 to precipitate sulfate and mercury oxide and separated. of the precipitate obtained.

Then, the solution freed from the mercury compounds is then subjected to re-acidification and electrolysis during which the zinc is deposited on the cathode and the manganese oxide is formed at the anode. In this way, manganese and zinc can be recovered selectively and thus separately.

Unfortunately, in this method of EP 620 607, the recovery of the compounds adsorbed on the various electrodes is painful and requires a high technicality and a considerable investment. There is therefore a need to find a new process for the selective recovery of zinc and manganese compounds in a simple manner and to obtain high performance to meet increasingly stringent waste reclamation standards given the current state of affairs. environmental problems.

The aim of the invention is to overcome the drawbacks of the state of the art by providing a method which makes it possible, in a very simple manner, to selectively recover manganese from zinc without using a complex electrolytic plant and which provides compounds that can be directly recycled in sectors. existing, without resorting to the development of new upgrading ancillary facilities.

To solve this problem, it is provided according to the invention, a method as indicated at the beginning, characterized in that it further comprises, before said step of selective recovery of the manganese and zinc compounds, a precipitation of zinc in the form of zinc sulphide using a compound selected from the group consisting of hydrogen sulphide, sodium, potassium, ammonium sulphide, and sodium, potassium, sodium hydrogen sulphide. ammonium, their derivatives and their mixtures.

The sulfide or hydrogen sulfide moiety does not react with the manganese which thus remains in salt form in solution while the sulfide or hydrogen sulfide moiety reacts with the zinc salt to form zinc sulfide.

Zinc sulphide is a valuable compound in industries that use natural zinc sulphide ore also known as blende.

In a particularly advantageous manner, the invention has made it possible, in a single step, to obtain zinc in solid form while keeping the manganese in liquid form, to obtain a zinc yield that is approximately 90% precipitated by elemental zinc. compared to total zinc contained in the black mass and, therefore, to meet the very stringent standards for the recovery of compounds from batteries.

In addition, the selective precipitation of zinc accompanied by the degree of purity of the products makes it possible to obtain a zinc compound for which a recovery process already exists. For example, zinc refineries that manufacture zinc ingots can reintroduce the zinc sulphide thus obtained into their production line and the recovered zinc (ZnS) compound thus becomes a secondary raw material.

The process according to the invention is therefore particularly ingenious and advantageous.

In a preferred embodiment, in the process according to the invention, said acid leaching is carried out in a reducing medium.

In this way, manganese of valence IV is reduced to manganese of valence II and thus becomes soluble. As a result, the recovery efficiency of manganese is improved.

Preferably, the reducing medium is obtained by the addition of a reducing agent selected from the group consisting of hydrogen peroxide, sodium thiosulfite, potassium, zinc metal powder, SO2 and others. similar reducing compounds and mixtures thereof and is preferably oxygenated water.

Oxygenated water is, in acidic medium as here, a reducing agent. After the reduction reaction, only water remains, and therefore hydrogen peroxide is a preferential reducing agent since it leaves no trace of its presence (no obtaining compounds requiring an additional recycling) .

Advantageously, the leaching in acid medium is preceded by an alkaline washing of the black mass with water and an alkaline compound selected from the group consisting of NaOH, KOH, LiOH, and their mixture.

The alkaline washing makes it possible to eliminate elements such as NH4 +, K + and CI 'because it allows an almost complete desorption of the components of the black mass.

In a particularly advantageous embodiment of the process according to the invention, said precipitation of zinc in the form of zinc sulphide is followed by an adjustment of the pH to a value of between 2 and 6, more particularly of between 2.5 and 4, more particularly about 3.

It is a matter of finding a compromise between two situations. If the pH is too low, the sulphide, mainly present as hydrogen sulphide gas, is removed from the medium and the precipitation yield of zinc sulphide falls. If the pH is too high, the Mn co-precipitates with the zinc sulfide and the separation has a diminished yield. Therefore, it was necessary to find a pH value at which the separation between zinc and manganese is optimal and at which the content of hydrogen sulfide that escapes is minimal.

In a particular form of the process according to the invention, said selective recovery of the manganese and zinc compounds is a liquid / solid separation in which a solid fraction comprising zinc sulphide is separated from a liquid fraction comprising the manganese salt.

This separation step is very easy and does not require expensive investment contrary to the process described in patent EP 620 607. In fact, it does not implement a complex process such as electrolysis or ozonation and allows a realization on a very large scale very easily.

In a particularly advantageous embodiment, the process according to the invention further comprises a precipitation of manganese in the form of a manganese hydroxide or in the form of a manganese dioxide.

In this case, the recovery of manganese is again very easily, by a simple liquid / solid separation. In addition, the precipitation can be carried out by adding caustic soda or any other alkaline agent, in the presence or absence of an oxidizing agent. As caustic soda is a common reagent, it is clear from this that the process according to the invention is particularly advantageous since it makes it possible to recover manganese easily while requiring the use of readily available reagents.

Manganese will be recovered as manganese hydroxide when caustic soda is added to the manganese salt solution.

The manganese will be recovered as manganese dioxide when caustic soda and hydrogen peroxide are added to the manganese salt solution.

Advantageously, the pH is kept constant during the recovery of manganese to a value of between 7 and 10.

Preferably, said precipitation of zinc in the form of zinc sulphide is carried out in the presence of a reducing agent chosen from the group of metallic zinc, sodium thiosulfite, potassium, hydrogen peroxide, and other compounds similar reducing agents and mixtures thereof and is preferably metallic zinc.

Metallic zinc maintains the manganese in solution without affecting the recovery efficiency of zinc. In addition, if a secondary reaction takes place between the solid zinc and the sulphide, no new foreign element to be removed is produced, but only one of the recoverable elements already produced by the invention is obtained.

Advantageously, the solid fraction containing the zinc precipitated in the form of zinc sulphide is washed and plumped in the presence of a mineral acid and optionally hydrogen peroxide to obtain a pulp.

In particular, said mineral acid selected from the group consisting of sulfuric acid, nitric acid, hydrochloric acid, and mixtures thereof.

In a particular embodiment, the pulp thus obtained is subjected to a pH adjustment by adding a basic compound until a pH value of between 2 and 6, more particularly between 2.5 and 4 and above, is obtained. especially about 3.

Preferably, said basic compound is selected from the group consisting of caustic soda, ammonia, zinc oxide, potassium hydroxide and their mixture.

In addition, in some cases, an organic polymer of cationic type is added to the pulp, which facilitates subsequent separation steps.

In another embodiment of the process according to the invention, the pulp undergoes a solid / liquid separation for separating a solid fraction of petrified zinc sulphide and a liquid fraction comprising a mixture of filtrate and washing water.

In addition, it may be appropriate according to the invention that the liquid fraction comprising the mixture of filtrate and washing water is injected into the acid leaching step of the black mass because it is indeed economical and ecological to recover a part or all the liquid fraction (acid) in the leaching step of the black mass.

In the process according to the invention, said at least one separation making it possible to isolate the black mass comprises at least one step chosen from: a magnetic separation making it possible to isolate the ferrous metals from the milled fraction, a granulometric separation, a densimetric separation and preferably includes all the steps mentioned. In addition, said separation steps may be preceded by manual sorting and / or mechanical screening of batches of harvested piles that allow the removal of foreign bodies, button cells and all unwanted batteries.

The batch of sorted batteries thus obtained then undergoes mechanical treatment of the cells comprising mechanical grinding of the batteries, preferably dry to obtain a fraction having an average size in the range of 0 to 15/20 mm, a magnetic separation of the ground material. to extract the ferrous metals from the crushed fraction and a granulometric fractionation of the crushed stone. The set of fractions produced therefore comprises the small particles called fine particles whose size is less than 3 mm, the particles of average size having a particle size between 3 and 5 mm (in some cases, this fraction can be non-existent if the screening is limited to two fractions) and larger particles larger than 5 mm. The latter undergo a densimetric separation that separates non-ferrous metals, carbon, plastics and paper. The recovered fractions are then separated by eddy currents.

In some cases, the fraction of the medium-sized particles is crushed again to be integrated in the fraction of the small particles, called fine particles, which constitutes the black mass called BM (Black Mass).

Other embodiments of the process according to the invention are indicated in the appended claims.

Other features, details and advantages of the invention will become apparent from the description given below, without limitation and with reference to the detailed examples.

The method according to the invention thus makes it possible to recover zinc and manganese from the piles collected.

The method according to the invention therefore comprises firstly a first sort (manual or not) batches of batteries harvested (removal of foreign bodies and unwanted batteries).

Then, a mechanical treatment is performed. Mechanical treatment includes mechanical grinding of alkaline and salt cells (all sizes combined). The mechanical grinding of the batteries, in particular dry, is carried out by a grinder / crusher which can be either a rotary mill with hammers or moving bars, or a percussion mill or a shredder or any other type of mill, to reduce the size of the batteries to fragments of 0 to 15/20 mm.

The ground material then undergoes a succession of separations (magnetic, granulometric, and densimetric) which make it possible to distribute the ground material in several fractions, the majority of which is recoverable.

The magnetic separation of the ground material is for example made by means of either an overband or a magnetic drum, to extract the ferrous metal fragments.

The ferrous-free ground material is divided into three categories comprising particles of larger size or greater than 5 mm, particles of intermediate size or between 3 and 5 mm and fine particles or particles having a size of less than 3 mm.

Granulometric fractionation may in some cases be limited to two fractions: fractions greater than 3 mm and fractions smaller than 3 mm. Particle size cuts at 3 and 5 mm can also vary depending on the operating conditions, the nature of the batteries at the inlet of the unit and the requirements imposed by the quality of the finished products or the conduct of the densimetric table.

The cuts can then be defined at 1, 2, 3, 4, ... or at 20 mm.

A qualitative separation, in two stages, of the particles of the largest dimension can then be carried out. It comprises on the one hand a densimetric fractionation (air table or jigging) which separates the particles of size greater than 5 mm in three categories: 1) the elements described as "heavy" such as fragments of zinc, brass, d carbon electrodes.

2) the elements qualified as "light" such as plastics, small metal fragments and carbon electrodes and 3) "very light" elements such as paper, cardboard .....

On the other hand, it includes a fractionation by Eddy Current (FDC) of the elements described as "light" in non-metallic elements called "plastics" which are composed mainly of fragments of plastic from the carcasses of stacks and small pieces of carbon, and non-ferrous metal elements called "non-ferrous". This type of fractionation is also applied to the elements described as "heavy", so as to separate the metal parts that will be mixed with "non-ferrous" from the fractionation of "light".

One of the fractions, the finer, is therefore, as already mentioned above, called the black mass (BM) and consists essentially of the inner part of the batteries and contains zinc compounds and manganese. This group "BM" is subjected to a hydrometallurgical treatment allowing the extraction and the recovery of its very high contents in zinc and manganese.

It includes the following steps:

Alkaline washing of the BM:

The "BM" is first plumped and washed in the presence of water in proportions ranging from 1.5 m3 / t to 3 m3 / t and preferably about 2 m3 / t and an alkaline compound, by example of sodium hydroxide in an amount ranging from 5 g / l to 40 g / l and preferably between 10 and 20 g / l. The pulp thus obtained is then filtered and rinsed with water, one or more times, in order to extract them. chlorides, ammonium, potassium and other soluble salts. A moist black mass is then obtained.

Extraction of zinc and manganese

Zinc and manganese are then extracted by pulping the "BM" thus obtained in an aqueous phase, in the presence of acid, in particular sulfuric acid, and when necessary hydrogen peroxide. Preferably, the sulfuric acid is added in a proportion of 1 to 2m3 and preferably about 1.2m3 of sulfuric acid at 50% by weight per ton of wet black mass. The oxygenated water is added, when it is present, in a proportion ranging from 0 to 0.3 m 3 and preferably from 0.2 m 3 of hydrogen peroxide to 35% by weight per ton of wet black mass (containing 20 to 25% by weight of moisture)

If the black mass is not previously washed, sulfuric acid is added at a rate of 1.2 to 2.3 m 3 and preferably about 1.3 m 3 of sulfuric acid at 50% by weight per ton. unwashed black mass (containing about 6 to 10% by weight of moisture). The oxygenated water is added, when it is present, in a proportion ranging from 0 to 0.35 m3 and preferably from 0.25 m3 of hydrogen peroxide to 35% by weight per ton of unwashed black mass (containing about 6 to 10% by weight of moisture).

The pH of the leach solution is adjusted by addition of a basic compound which may be caustic soda, ammonia, zinc oxide or manganese, magnesia, potassium hydroxide and the like. Preferably, the pH is adjusted by the addition of sodium hydroxide, until a pH value of between 2 and 6, more particularly between 2.5 and 4, more particularly about 3, is obtained.

It is understood that the present invention preferably uses sulfuric acid to solubilize zinc and manganese because it is the reference acid for the extraction of zinc compounds, but other acids such as nitric acid or hydrochloric acid and mixtures thereof can also be used. Similarly, when necessary, oxygenated water is preferably used as reducing agent in an acid medium, but other compounds such as zinc metal in powder form could also be used.

Indeed, as already mentioned above, the acid leaching can be carried out in a non-reducing medium as long as the desired recycling yield can be obtained without its presence.

In a particular embodiment, a flocculant such as an organic polymer may be added to improve the yield of the next separation step.

The pulp then undergoes solid / liquid separation by filtration or centrifugation. For example, the filtration may be carried out using a filter press, a band filter, a plate filter or the like.

Filtration or centrifugation of the pulp to separate a mixed solution rich in zinc sulphate and manganese and a solid residue containing carbon and manganese to be destroyed or upgraded in a subsidiary die. The manganese content in this residue is 15% by weight of manganese relative to the dry weight of residue if the acid leaching was carried out in a reducing medium and 35% by weight of manganese relative to the dry weight of residue if the lixiviation acid was carried out in a non-reducing medium.

Selective recovery of zinc and manganese compounds

The mixed solution rich in zinc and manganese salts then undergoes precipitation of zinc in the form of zinc sulphide using a compound chosen from the group consisting of hydrogen sulphide, sodium sulphide and potassium sulphide. ammonium, sodium hydrogensulfide, potassium, ammonium, their derivatives and mixtures thereof. Preferably, the compound allowing the precipitation of zinc in the form of a sulphide is a reagent based on Na2S and / or NaHS which is added in an amount necessary to reach a zinc content of between 2 and 100 mg / l in the final salt solution. This quantity is equivalent, for example, to Na2S at 1.05 times the stoichiometry of zinc and, in the case of NaHS, to 1.3 times the stoichiometry of zinc, considering the total zinc content in the mixed salt of zinc. departure.

In addition, a reducing agent which is selected from the group of metallic zinc, hydrogen peroxide, sodium thiosulfite, potassium, sodium hypochlorite, potassium, and other similar reducing compounds and mixtures thereof and is preferably metallic zinc. The reducing agent is added in a proportion ranging from 5 to 10 kg / m 3 of zinc salt solution.

In addition, the pH of the resulting suspension is adjusted to a value between 2 and 6, more particularly between 2.5 and 4, more particularly about 3, by addition of a basic compound as above. However, according to the invention, preference will be given to caustic soda for this purpose.

Advantageously, zinc sulphide (ZnS) is obtained by at least one of the following reactions, or both in some cases:

ZnS04 + Na2S * · ZnS + Na2SO4

ZnS04 + NaHS * ZnS + NaHS04

In a preferred form according to the invention, a flocculating agent such as a cationic polymer may be added to facilitate the next separation step.

The suspension then undergoes a solid / liquid separation by filtration or centrifugation of the aforesaid suspension. For example, the filtration may be carried out using a filter press, a band filter, a plate filter or the like.

Filtration of the pulp makes it possible to separate a solid fraction which comprises the zinc sulphide obtained which will then be purified and a liquid fraction comprising at least manganese sulphate which will be further treated.

The yield obtained of precipitated zinc sulphide is generally in the range of 95 to 100% and corresponds to the ratio of the weight of elemental Zn recovered as sulphide to the weight of elemental Zn present in the mixed solution of zinc sulphate and of manganese starting.

The solid fraction is optionally washed and then plumped in the presence of sulfuric acid and hydrogen peroxide. Preferably, the sulfuric acid is added in a proportion ranging from 150 to 350 liters of sulfuric acid at 50% by weight per tonne of dry ZnS or, more simply, in an amount necessary to reach a pH of 3.

Hydrogen peroxide is added in a proportion ranging from 2 to 7 and preferably about 4 times the stoichiometry of the manganese present in the ZnS to be purified.

The pH of the thus-obtained pulp is adjusted, optionally, by the addition of a basic compound which may be caustic soda, ammonia, zinc oxide, potassium hydroxide and the like. Preferably, the pH is adjusted by the addition of caustic soda, until a pH value of between 2 and 6, more particularly between 2.5 and 4, and more particularly of about 3, is obtained.

It is understood that the present invention preferably uses sulfuric acid to purify zinc, but other acids such as nitric acid or hydrochloric acid and mixtures thereof can also be used.

In a particular embodiment, a flocculating agent such as a cationic organic polymer may be added to facilitate the next separation step.

The pulp then undergoes solid / liquid separation by filtration or centrifugation of the pulp. For example, the filtration may be carried out using a filter press, a band filter, a plate filter or the like.

Preferably, the pulp will be filtered on a filter press with washing of the filter cake by injection of water until a conductivity of 80 μS / cm to 150 μS / cm is obtained, preferably 100 to 150 μS / cm.

Filtration or centrifugation of the pulp makes it possible to separate a solid fraction comprising the purified ZnS (the yield reaching values of approximately 90% by weight of elemental zinc recovered relative to the elemental zinc present in the dry black mass) and a fraction liquid consisting of a mixture of the filtrate and washing water, which will be subsequently used in some embodiments economically advantageous and environmentally friendly to pulp the "BM" during the extraction of zinc and manganese.

The manganese sulphate solution can be recycled as such into existing recovery channels.

In a particular form of the invention, the method according to the invention further comprises a step of recovering manganese.

The recovery of manganese begins with a precipitation of the latter followed by a solid liquid separation.

Precipitation of manganese as Mn (OH)? or

MnO?

Two ways of precipitation are possible.

The first route involves the addition of caustic soda (or other equivalent alkaline agent) to obtain manganese as Mn (OH) 2. Soda is added at a concentration of about 1.4 to 1.5 g of NaOH per gram of manganese.

The second route comprises the addition of caustic soda (or other equivalent alkaline agent) and hydrogen peroxide to obtain manganese in the form of MnO 2. The sodium hydroxide is added at a concentration of about 1.4 to 1, 5 g of NaOH per gram of manganese, while the oxygenated water is added at a concentration of between 1 and 4 g of H 2 O 2 to 35% by weight per gram of manganese and preferably about 2 g of hydrogen. C. 35% by weight per gram of manganese.

In this case, hydrogen peroxide acts as an oxidant and thus allows to obtain manganese dioxide in the form Mn02 (valency of IV manganese). Of course, other oxidizing agents such as potassium permanganate and sodium hypochlorite may also be used. The pH is about 8 at this stage, as long as hydrogen peroxide has been used.

A flocculant such as an anionic organic polymer may be added to facilitate the next separation step.

The suspension then undergoes a solid / liquid separation by filtration or centrifugation of the pulp. For example, the filtration may be carried out using a filter press, a band filter, a tray filter or the like.

Filtration of the pulp makes it possible to separate a solid fraction consisting of Mn (OH) 2 or MnO 2 and of a liquid fraction rich in Na 2 SO 4 which is oriented towards an auxiliary treatment die.

It goes without saying that during the liquid / solid separation or just after, the filter cake (solid fraction) can be washed to increase the purity of the precipitate obtained.

In the case of a reducing acid leaching, the recovery yield of manganese is about 77% by weight of extracted elemental Mn relative to the weight of elementary Mn present in the dry black mass, when it is precipitated. in the form of MnC 2 or when the latter is precipitated in the form of Mn (OH) 2.

In the case of acid leaching in a non-reducing medium, the recovery yield of manganese is about 37% by weight of elemental parη relative to the weight of Mn present in the dry black mass.

EXAMPLE 1 - Sulfuric leaching in the presence of HaOl 100 kg of black mass were leached into a leach solution containing 120 liters of 50% by weight sulfuric acid, 22 liters of 35% hydrogen peroxide and 137 liters of sulfuric acid. water. The pH of the solution was adjusted to about 3 with caustic soda solution. The suspension thus obtained was then filtered on a filter press and the residue washed with approximately 20 liters of water to recover a maximum of zinc and manganese. About 300 liters of mixed solution of ZnSO 4 and MnSO 4 and 48 kg of crude residue are recovered.

Starting from 100 liters of mixed zinc sulphate and manganese solution, 700 g of zinc metal are added beforehand.

Then, a 2M aqueous Na 2 S solution is then gradually injected into the bottom of the tank at a rate of 45 to 75 liters depending on the concentration of Zn in the mixed solution. This injection method limits the degradation of the sulfide reagent and increases its time of presence in the solution. The precipitation yield of zinc to sulphide is therefore improved. The pH of the solution is maintained at about 3 by addition of sulfuric acid. After the addition of a quantity of Na2S corresponding to about once the zinc stoichiometry, the zinc content of the solution is verified. When the zinc content in the solution reaches 4 to 100 ppm, a cationic type flocculant is added which facilitates the filtration and washing of the precipitate on a filter press.

The recovered zinc sulphide precipitate is analyzed for Mn content. The latter, once known, allows to estimate the amount of hydrogen peroxide necessary for the subsequent purification of the sulphide since it corresponds to four times the Mn stoichiometry present in ZnS.

100 kg of crude ZnS was suspended in water and the pH of the suspension was adjusted to 3 with sulfuric acid. 35% hydrogen peroxide is gradually added in small quantities to avoid its own degradation. The pH is maintained at around 3 for the duration of the addition. Suspended zinc sulphide, of pale pink origin, catches a white color. Once the total amount of H 2 O 2 35% has been added, the suspension is filtered and washed on a filter press. Washing is maintained until the wash water at the outlet of the filter has a conductivity less than 100 - 150pS / cm. The result is a white ZnS cake with a degree of purity of between 65 and 90%.

The addition of a cationic flocculant before filtration is advantageous for limiting filter clogging, reducing the filtration time and improving the efficiency of the washing. The addition of Na2S, during the purification phase, is frequent in order to limit the amount of zinc which is solubilized simultaneously with the manganese.

The formation of manganese dioxide is carried out starting from the manganese sulphate solution, which generally has a Mn content around 30 g / l. This content is accurately determined before the formation of MnO 2 to adjust the required amounts of soda and hydrogen peroxide. Starting from 100 liters of 30 g / l solution in Mn, the equivalent of approximately 5.5 liters of 50% sodium hydroxide and between 4.5 and 5 liters of 35% H2O2 are gradually added. When the Mn content reaches less than 300 ppm, the suspension is filtered and optionally washed. The addition, beforehand, of anionic flocculant is useful. The equivalent of 4 to 5 kg dry of MnO 2 is obtained.

EXAMPLE 2 - Sulfuric leaching without H? Q? 100 kg of black mass were leached in 101 liters of 50% sulfuric acid and 140 liters of water. The pH of the solution is raised to around 3 with sodium hydroxide in solution. The suspension is filtered through a filter press and the residue is washed. About three hundred liters of mixed solution of ZnSO4 and MnSO4 at a concentration of 54 g / l in Zn and 29 g / l in Mn are obtained. The following selective separation steps are identical to those described in Example 1.

About 72 kg of crude residue are recovered, most of which is MnO 2.

It is understood that the present invention is in no way limited to the embodiments described above and that many modifications can be made without departing from the scope of the appended claims.

Claims (16)

1. A method for treating alkaline and salt batteries comprising the steps of: - mechanical grinding of said batteries to obtain a crushed battery including ferrous metals, non-ferrous metals and a fine fraction called black mass (BM) containing compounds zinc and manganese, - at least one separation allowing to isolate the black mass, - an acid leaching of the black mass making it possible to obtain a mixed solution of manganese and zinc salts by means of a mineral acid, a solid / liquid separation making it possible to recover said mixed solution of manganese salt and zinc, and selective recovery of the manganese and zinc compounds, characterized in that it comprises, in addition, before said step of selective recovery of the compounds of manganese and zinc, precipitation of zinc as zinc sulphide using a compound selected from the group consisting of hydrogen sulphide, Sodium, potassium, ammonium, sodium, potassium, ammonium hydrogen sulphide, their derivatives and mixtures thereof. 2. The method of claim 1, wherein said acid leaching is carried out in a reducing medium. 3. Process according to claim 2, in which the reducing medium is obtained by the addition of a reducing agent chosen from the group consisting of hydrogen peroxide, sodium thiosulfite, potassium and zinc metal powder, SO 2 and other similar reducing compounds and mixtures thereof and is preferably hydrogen peroxide. A process according to any one of the preceding claims, wherein the acidic leaching is preceded by an alkaline wash of the black mass with water and an alkaline compound selected from the group consisting of NaOH. , KOH, LiOH, and their mixture. 5. A process according to any one of the preceding claims, wherein said precipitation of zinc in the form of zinc sulphide is carried out by adjusting the pH to a value between 2.5 and 4, more particularly about 3. . A process according to any one of the preceding claims, wherein said selective recovery of the manganese and zinc compounds is a liquid / solid separation in which a solid fraction comprising the zinc sulfide is separated from a liquid fraction comprising the sulphate of manganese. The process of any of the preceding claims further comprising precipitating manganese as a manganese hydroxide or as a manganese dioxide. 8. A process according to any one of the preceding claims, wherein said precipitation of zinc in the form of zinc sulphide is carried out in the presence of a reducing agent selected from the group of zinc metal, a sodium thiosulfite, potassium , hydrogen peroxide, and other similar reducing compounds and mixtures thereof and is preferably metallic zinc. 9. Process according to any one of claims 6 to 8, wherein the solid fraction containing the zinc precipitated in the form of zinc sulphide is washed and plumped in the presence of a mineral acid and optionally hydrogen peroxide to obtain a pulp. The process of any one of the preceding claims, wherein said mineral acid is selected from the group consisting of sulfuric acid, nitric acid, hydrochloric acid, and mixtures thereof. 11. The method of claim 9 or 10, wherein the pulp thus obtained is subjected to a pH adjustment by addition of a basic compound to obtain a pH value of between 2 and 6, more particularly between 2, 5 and 4 and more particularly about 3. The process of claim 11, wherein said basic compound is selected from the group consisting of caustic soda, ammonia, zinc oxide, potassium hydroxide, and mixtures thereof. 13. A process according to any one of claims 9 to 12, wherein an organic polymer of cationic type is added to the pulp. 14. A method according to any one of claims 9 to 13, wherein the pulp undergoes a solid / liquid separation for separating a solid fraction of purified zinc sulphide and a liquid fraction comprising a mixture of filtrate and washing water. . The process according to claim 14, wherein the liquid fraction comprising the mixture of filtrate and wash water is injected into the acid leaching step of the black mass. 16. A method according to any one of the preceding claims, wherein said at least one separation for isolating the black mass comprises at least one step selected from: a magnetic separation for isolating ferrous metals from non-ferrous metals, a separation particle size, a densitometric separation and preferably comprises all the steps mentioned.