OA21265A - Integrated phosphoric acid decadmization process. - Google Patents

Abstract

The present invention relates to an integrated process for decadmation of phosphoric acid, comprising:attack (1) of phosphate (Ph) with sulfuric acid (AS) in a reactor so as to prepare a solution of phosphoric acid containing cadmium and calcium sulfate dihydrate or hemihydrate, concentration (2) of said phosphoric acid solution, so as to form a concentrated phosphoric acid (PA) having a mass content between 42% and 61% in P2O5, addition (3) of sulfuric acid (AS) to adjust the free sulfate content, anhydrite being formed by recrystallization of calcium sulfate dihydrate and hemihydrate, cadmium co-crystallizing with said anhydrite, so as to obtain decadmium phosphoric acid and anhydrite sludges rich in cadmium, desulfation (4) of the decadmium-containing phosphoric acid, desupersaturation (5) and clarification (6) by decantation of the mixture of decadmium-containing phosphoric acid and the sludge, conditioning (7) of said sludge (Psi ) with a solution of phosphoric acid (APd) having a mass titer of less than or equal to 61% in P2O5, recycling of the conditioned sludge (Ps2) in step (1) of attacking the phosphate.

Description

INTEGRATED PROCESS FOR DECADMIATION OF PHOSPHORIC ACID

FIELD OF THE INVENTION

The present invention relates to an integrated process for decadmation of phosphoric acid by co-crystallization of cadmium in the crystal lattice of calcium sulfate anhydrite.

STATE OF THE ART

Phosphoric acid (H3PO4) is an essential product for the manufacture of fertilizers, notably ternary NPK fertilizers, or binary NP fertilizers, as well as triple superphosphate (TSP).

Phosphoric acid after purification is also used in the manufacture of food products, in particular for the acidification of drinks, or even for the treatment of metal surfaces, in the field of microelectronics or in the pharmaceutical field.

Phosphate rocks are important sources of raw material for the manufacture of phosphoric acid. Phosphoric acid can be produced mainly by two methods: wet process and thermal process. The wet process is the most used and the phosphoric acid resulting from this route can be used to produce 20 phosphate fertilizers (DAP or diammonium phosphate, MAP or monoammonium phosphate, TSP or triple superphosphate). The acid obtained by thermal process is of higher purity and is generally used for pharmaceutical products or food products.

In a wet process production unit, phosphoric acid is produced in particular by the action of a strong acid on natural phosphate ore. Sulfuric acid is the most commonly used strong acid. In this case, insoluble calcium sulfate is formed which is separated by filtration to recover said insoluble calcium sulfate. The operating conditions are chosen in order to precipitate the calcium sulfate either in its dihydrate form (phosphogypsum), producing phosphorus pentoxide P2O5 generally at a concentration of 26-32% at 70-80 ° C, or in its hemihydrate form , with P2O5 generally at a concentration of 40-52% at 90-110°C. Evaporation can be used to further concentrate the phosphoric acid subsequently and thus optimize its quality.

The presence of impurities in phosphoric acid influences the operation of phosphoric acid manufacturing units and the quality of finished products. In particular, 35 several studies on the subject highlight the effect of impurities contained in phosphoric acid on corrosion and clogging of equipment, as well as on the viscosity and coloring of the acid.

Other work has revealed the toxic effect of certain impurities in products using phosphoric acid as an intermediate product.

Cadmium is one of the elements that has experienced strong restrictions at limit levels in phosphate and in derived products. Indeed, during the manufacture of phosphoric acid using the wet method using sulfuric acid, the impurities originating from the phosphate rock are distributed between the phosphoric acid and the calcium sulfate.

Phosphate manufacturers are therefore increasingly faced with regulatory restrictions regarding certain elements present in their products. Heavy metals, and particularly cadmium (Cd), are subject to regulations which limit their content in phosphate and phosphate derivatives.

Regarding cadmium, in addition to the limit limit set at 60 mg/kg P2O5, the European Union is preparing to implement a low cadmium content label applicable to products with a cadmium content of less than 20 mg. /kg P2O5.

In this context, the development of efficient decadmization processes, i.e. making it possible to significantly reduce the quantity of cadmium in the phosphate product, and particularly in the phosphoric acid, is therefore decisive.

To this end, document FR2687657 describes a process for decadmiation of a phosphoric acid solution based on an adjustment of the solid content and the sulfuric acid in an evaporator reactor operating at a temperature ranging from 84°C to 92° vs. This adjustment 20 is carried out for a solid content of between 1.3 and 6% in order to have an excess of free calcium sulfate of between 1.5 and 6%, this making it possible to have a phosphoric acid with a Cd content. less than 10ppm.

The document WO2014027348 describes a process for manufacturing phosphoric acid with a reduced content of cadmium and calcium sulfate, which process comprises the steps 25 which consist of mixing crude phosphoric acid, having a P2O5 concentration between 45 and 55 % and containing up to 50 ppm of cadmium, with concentrated sulfuric acid, to obtain a calcium sulfate concentration of 4 to 12%; to add 5 to 15% of natural phosphate rock to the mixture, so as to obtain phosphoric acid and suspended particles of calcium sulfate; then filtering said 30 particles at a temperature of at least 80°C. However, this process is characterized by the generation of a significant quantity of sludge leading to a significant loss of phosphoric acid, which affects the overall cost of the process and complicates operability. This cadmium-containing sludge is filtered through a sludge filter or slurry filter. However, the very fine characteristic of the solid generated, and the dynamic viscosity of the cadmium sludge, lead to enormous filtration difficulties inducing significant losses of P2O5, in addition to significant clogging of the filter.

Document WO2008113403 describes a process for treating cadmium solids comprising calcium sulfate anhydrite and/or hemihydrate having a cadmium content, characterized in that it comprises an extraction of cadmium from said cadmium solids by bringing them into contact with a aqueous solution of alkali metal sulfate, and a solid/liquid separation between a solid phase based on calcium sulfate dihydrate with cadmium content depleted relative to said cadmium content of calcium sulfate 5 anhydrite and/or hemihydrate and a phase aqueous solution containing alkali metal sulfate and cadmium in solution. However, this process, which focuses on the problem of managing cadmium sludge by filtration and then extraction of cadmium from solid calcium sulfate, does not provide a solution to the P2O5 losses induced by the filtration of cadmium sludge.

Document EP0253454 describes a process for removing cadmium from phosphoric acid, based on the co-crystallization of cadmium in calcium sulfate anhydrite. This process, specially designed for the hemihydrate and phosphonitric acid processes, only seems to apply to slightly concentrated acids (44% P2O by weight) and at temperatures ranging from 90 to 110°C. In addition, this process uses a solid content of 10%, for an acid with 44% P ₂ O ₅ by weight. Decadmization takes place in the presence of a significant sulfuric excess of 8% (for an acid 44% P2O5), which requires desulphation after decadmation. Desulfation is done by adding phosphate under conditions which have not been indicated. However, this process generates a voluminous and poorly concentrated discharge of cadmium sludge which is subsequently filtered and causes losses in

P ₂ O ₅ .

Document WO1991000244 describes a process allowing the elimination of cadmium by co-crystallization of a precipitate based on calcium, cadmium, sulfates and phosphate ions. This process uses concentrated acid 50-60%P ₂ Os, in the presence of a sulfuric excess of 1 to 7% and at high temperature (120°C). The calcium is introduced in a soluble form obtained by attacking the phosphate with concentrated phosphoric acid at 120°C. However, this process, in addition to the complication generated by the multitude of reactors used, requires a very high temperature in a phosphosulfuric medium which would require the use of noble and therefore expensive materials. The problem of managing decadmium sludge by filtration remains a weak point of the process relative to operability and P2O5 losses.

Document MA23803 describes a process for producing decadmium phosphoric acid by co-crystallization of cadmium with calcium sulfate. Decadmization takes place on the acid at the exit of the concentration stage, at the temperature of this acid. According to this process, the decadmization conditions consist of the introduction into the concentrated acid (45-60% P ₂ O ₅ ) of calcium sulfate in hemihydrate or dihytrate form at a solid content varying between 0.5 and 10% and readjust the sulfuric level of phosphoric acid at a content between 60 and 120 g/L. The temperature can vary between that of the acid leaving the concentration stage and 50°C. Desulfation takes place in the presence of phosphate. The decadmation and desulphation sludge can be recycled to the attack tank, to the calcium sulfate filter, or can be separated by conventional separation methods such as decantation, filtration and/or centrifugation with a view to their processing or storage. However, this process does not provide an operational and economical solution for the management of cadmium sludge by recycling to the attack tank or to the calcium sulfate filter. Indeed, in the phosphoric acid production industry, the recycling of calcium phosphate sludge with 45 to 60% P ₂ O ₅ from the decantation outlet to the rock attack tank, induces a significant loss of syncrystallized P2O5 due to the high viscosity of the sludge, also IO there is a negative impact on filtration following the deterioration of the crystallization of calcium sulfate by addition of a large quantity of hemihydate and anhydrite crystals known for their poor morphology and filtration. Recycling on the filter reduces the filtration speed of the calcium sulfate slurry, by blocking the filter cloth due to the fineness of the solid hemihydrate and anhydrite particles provided by the sludge, and by viscosity of the sludge.

STATEMENT OF THE INVENTION

An aim of the invention is to propose an integrated process for decadmization of phosphoric acid making it possible to overcome the drawbacks described above.

The invention proposes an integrated process for decadmiation of phosphoric acid by co-crystallization of cadmium in the crystal lattice of calcium sulfate anhydrite, making it possible, compared to state-of-the-art processes, to minimize P2O5 losses, to obtain a very high decadmization yield and a high P2O5 concentration of the decadmified phosphoric acid at the end of the process.

More precisely, the invention proposes an integrated process for the decadmation of phosphoric acid, comprising the following steps:

- attack of phosphate by sulfuric acid in a reactor so as to prepare a solution of phosphoric acid containing cadmium and calcium sulfate dihydrate or hemihydrate,

- concentration of said phosphoric acid solution, so as to form a concentrated phosphoric acid having a mass content between 42% and 61% in P2O5, preferably between 48% and 61%,

- addition of sulfuric acid to the concentrated phosphoric acid to adjust the free sulfate content in the mixture of sulfuric acid and phosphoric acid to a content of between 1.5% and 10% by weight of the mixture, preferably between 2.5% and 9% by weight of the mixture, anhydrite being formed by recrystallization of calcium sulfate dihydrate and hemihydrate, cadmium co-crystallizing with said anhydrite, so as to obtain decadmium phosphoric acid and anhydrite sludge rich in cadmium,

- desulfation of the decadmium phosphoric acid, in the presence of the phosphate to have in said phosphoric acid a solid content of between 1 and 15% by weight, preferably 7% by weight, and a sulfate content of between 1% and 5 % by weight, preferably 3% by weight;

- desupersaturation and clarification by decantation of the mixture of decadmium phosphoric acid and anhydrite sludge rich in cadmium, in order to separate the final phosphoric acid (Pli) having a cadmium content less than 10 ppm, or even less than 2 ppm, and sludge rich in cadmium,

- conditioning of said anhydrite sludge rich in cadmium with a solution 10 of phosphoric acid having a mass titer less than or equal to 61% in P2O5,

- recycling of conditioned sludge in the phosphate attack stage with sulfuric acid.

By “integrated”, we mean in this text that the decadmization process is incorporated into a phosphoric acid and fertilizer manufacturing line, in the sense that the transfers of flows (phosphate, phosphoric acid, sulfuric acid , water, steam, sludge, etc.) are operated and controlled as part of a single transformation chain. In other words, the decadmization process, the subject of the present invention, is an integral part of the phosphoric acid and fertilizer manufacturing chain.

According to advantageous but optional characteristics, possibly taken in 20 combination:

- the decadmization and desulfation steps are implemented simultaneously;

- the decadmization and desulphation stages are implemented successively;

- the decadmization of the phosphoric acid is carried out at a temperature between 50 and 120°C, preferably above 70°;

- the decadmization of phosphoric acid and the desulfation of decadmified phosphoric acid are carried out in a single reactor;

- the decadmization of the phosphoric acid is carried out at a pressure between 10 ⁴ and 10 ⁵ Pa;

- the step of conditioning the cadmium-rich anhydrite sludge includes an adjustment of the cadmium content, the P2O5 content, the solid content, the temperature and/or the viscosity of said sludge;

- in the conditioning step, the anhydrite sludge rich in cadmium has a temperature of between 40 and 60°C, preferably equal to 50°C, and a solid content of between 5 and 25%, preferably equal to 10%;

- in the conditioning step, the phosphoric acid solution has a mass titer of less than 30% in P2O5, preferably less than 20% in P2O5, and more preferably less than 10% in P2O5;

- to mix the anhydrite sludge rich in cadmium with the phosphoric acid solution, said phosphoric acid solution (APd) is at a temperature greater than or equal to 40°C, preferably greater than 50°C, and more preferably greater than 60°C;

- the conditioned sludge has a temperature of between 40 and 80°C, preferably equal to 47°C, and a solid content of between 5 and 20% by weight, preferably equal to 10%;

- during the recycling stage, the conditioned sludge is introduced into the phosphate attack reactor with sulfuric acid;

- during the recycling stage, the conditioned sludge is filtered with calcium sulfate dihydrate or hemihydrate obtained by the attack reaction on phosphate with phosphoric acid.

BRIEF DESCRIPTION OF THE FIGURES

Other advantages and characteristics of the invention will appear on reading the following description given by way of illustrative and non-limiting example, with reference to Figure 1 which is a diagram illustrating the main stages of the acid decadmization process. phosphoric according to the invention.

DETAILED DESCRIPTION OF EMBODIMENTS

The invention relates to an integrated process for decadmiation of phosphoric acid by co-crystallization of cadmium in the crystal lattice of calcium sulfate anhydrite, making it possible, compared to state-of-the-art processes, to minimize P2O5 losses, to obtain a very high decadmization yield and a high P2O5 concentration of the decadmified phosphoric acid at the end of the process.

According to a first step of the process, referenced 1 in Figure 1, a solution of phosphoric acid containing cadmium and insoluble calcium sulfate is prepared, which can be dihydrate or hemihydrate, according to the process for producing phosphoric acid. . To do this, sulfuric acid is reacted with natural phosphate ore.

According to the dihydrate process, sulfuric acid (AS) is reacted with phosphate ore (Ph) in a first reactor. Preferably, it is natural phosphate ore.

Reaction (a) is as follows, and leads to the formation of phosphoric acid H3PO4 35 and phosphogypsum CaSO ₄ (H ₂ O)2 and hydrofluoric acid HF:

Ca ₅ (PO ₄ ) ₃ F + 5 H ₂ SO ₄ + 10 H ₂ O -> 3 H ₃ PO ₄ + 5 CaSO ₄ .2H ₂ O + HF (a)

After reaction, the mixture is filtered. A filtrate comprising phosphoric acid is recovered, and a residue in the filter comprising calcium sulfate dihydrate.

Then, a step of concentration of the phosphoric acid obtained, referenced 2 in Figure 1, is carried out so that the titer by weight of the phosphoric acid is between 42% and 61% in P2O5, preferably between 48% and 61% in P2O5. This concentration step is integrated into the decadmization process. This makes it possible to avoid having to resort to an evaporator reactor, thus reducing the cost of the process.

The phosphoric acid (PA), possibly decanted, has a solid content of less than 6% by weight, or even less than 4% by weight relative to the weight of the phosphoric acid solution.

According to the hemihydrate process, sulfuric acid (AS) is reacted with phosphate ore (Ph) in a first reactor, the temperature being 90°C to 100°C. Preferably, it is natural phosphate ore.

Reaction (b) is as follows, and leads to the formation of phosphoric acid H ₃ PO ₄ and calcium sulfate hemihydrate CaSO ₄ % (H2O) and hydrofluoric acid HF:

Ca ₅ (PO ₄ ) ₃ F + 5 H ₂ SO ₄ + 5/2 H ₂ O -> 3 H ₃ PO ₄ + 5 CaSO ₄ . 1/2 H ₂ O + HF (b)

After reaction, the mixture is filtered. A filtrate comprising phosphoric acid is recovered, and a residue in the filter comprising calcium sulfate hemihydrate.

Then, we can treat the acid as it is which has a titer by weight of the phosphoric acid between 40% and 50%, or we carry out a step of concentration of the phosphoric acid obtained, so that the titer by weight of the phosphoric acid is between 50% and 61% in 20 P2O5. This avoids the need for an evaporator reactor, thus reducing the cost of the process.

The phosphoric acid (PA), possibly decanted, has a solid content of less than 6% by weight, or even less than 4% by weight relative to the weight of the phosphoric acid solution.

The concentration step is typically carried out at a temperature between 70 and 80°C.

Whatever the process (dihydrate or hemihydrate), the phosphoric acid (PA) is then readjusted by adding sulfuric acid (AS), in order to have a free sulfate level of between 1.5% and 10% in weight, preferably between 2.5% and 9% by weight, in the mixture obtained. This is the decadmization step by co-crystallization, referenced 3 in Figure 1. Decadmization can take place in a single reactor, or even several. The decadmization is carried out at a temperature between 50 and: 120°C, preferably above 70°C in order to allow the formation of anhydrite, that is to say anhydrous calcium sulfate CaSO ₄ , by recrystallization calcium sulfate dihydrate and 35 hemihydrate.

Due to the fact that the phosphoric acid obtained in the concentration step has a certain sulfate content, the consumption of sulfuric acid during the decadmization process can be minimized.

During the decadmiation reaction, the cadmium becomes trapped in the anhydrite crystals. In other words, cadmium co-crystallizes with anhydrite resulting from recrystallization of calcium sulfate dihydrate and hemihydrate. We therefore obtain anhydrite sludge rich in cadmium, separable from decadmium-containing phosphoric acid.

Desulfation of the decadmium phosphoric acid solution (step 4 in Figure 1) takes place in the presence of phosphate. The quantity of phosphate to add depends on its CaO content and the sulfate content that we want to achieve. According to this process, the phosphate is introduced into the phosphoric solution to have a solid content of between 1 and 15% by weight, preferably 7% by weight, and a sulfate content of between 1% and 5% by weight, preferably 3% by weight.

The process allows decadmization and desulfation simultaneously or separately. In fact, it takes advantage of the difference that exists between the kinetics of decadmization and desulfation. Decadmization and desulfation can take place in a single reactor, which greatly simplifies the process.

Additionally, since the temperature of the phosphoric acid is high during the concentration step, additional heating energy is saved during decadmization and subsequent process steps.

Steps 5 and 6 in Figure 1 correspond respectively to the desupersaturation and clarification by decantation of the mixture of decadmium phosphoric acid and anhydrite sludge rich in cadmium, in order to separate the final phosphoric acid (Pli) having a content in cadmium less than 10 ppm, or even less than 2 ppm following the co-crystallization of cadmium in anhydrite crystals, and cadmium-rich sludge (Psi) consisting mainly of anhydrite crystals.

Decadmiation is carried out at atmospheric pressure, that is to say a pressure of 1 atmosphere or 760 mmHg (10 ⁵ Pa), or even at negative pressure up to 80 mmHg (10 ⁴ Pa).

The liquid phase P _L i represents the final phosphoric acid with a low cadmium content resulting from the integrated decadmization process. She is recovered and can possibly undergo other further treatments.

Sludge rich in cadmium (Psi), having a temperature of between 40 and 60°C, preferably of the order of 50°C, a solid content of between 5 and 25%, preferably of the order of 10 %, undergo a conditioning treatment, step 7 in Figure 1, by mixing with a solution of diluted phosphoric acid (APd) having a P2O5 titer less than or equal to 61% in P2O5. Preferably, a diluted phosphoric acid solution is used whose mass titer is less than 30% in P2O5, preferably less than 20% in P ₂ O ₅ , and more preferably less than 10% in P2O5.

The temperature of the dilute phosphoric acid (APd) solution is greater than 40°C, preferably greater than 50°C, and more preferably greater than 60°C.

The conditioning treatment of cadmium-rich sludge consists of adjusting the composition of the cadmium-rich sludge in terms of cadmium content, P ₂ O ₅ content, solid content, temperature and viscosity.

The conditioned sludge thus obtained (Ps2), having a temperature of between 40 and 80°C, preferably of the order of 47°C, and a solid content of between 5 and 20% by weight, preferably of order of 10%, are recycled in the phosphate attack stage (stage 1 in Figure 1), where they are introduced into the attack reactor, or filtered at the level of the filtration operation, directly as a mixture with the slurry of calcium sulfate dihydrate or hemihydrate obtained at the level of the phosphate attack reaction,

This sludge conditioning treatment method is an integrated technical solution for the management of cadmium-rich sludge, which makes it possible to minimize P2O5 losses, reduce the investment and the footprint of the installation, as well as increase the P ₂ Os titer at the phosphoric acid preparation stage, and the P2O5 yield of the integrated decadmization process.

The sludge conditioning treatment method therefore solves all the problems of managing cadmium sludge presented in previous patents, namely the losses in P ₂ O ₅ during the filtration of the sludge (yield in P2O5), the investment in filtration, the footprint of the installation, the management of the solid anhydrite cake rich in cadmium after filtration of the sludge, known for its rapid massing and its great hardness posing evacuation difficulties.

The integrated decadmization process according to the invention makes it possible to have a P2O5 yield greater than 99% following the conditioning treatment and recycling of the conditioned sludge.

EXAMPLES

The following non-limiting examples illustrate embodiments of the invention. The percentages given are all by mass.

Example 1

In a phosphoric acid solution having a composition of 52% P2O5, 3% solid, 2% sulfates and titrating 38 mgCd/KgP ₂ O5, 67g of 98% sulfuric acid is introduced to reduce the sulfates to 6% . The temperature is maintained at 70°C.

After decantation of the decadmium acid, the cadmium content in the phosphoric acid is 8 mgCd/KgP ₂ Os with a solid content of 0.5% and a sulfate content of 1%. The sludge after conditioning is recycled in the phosphate attack. The P2O5 yield of the integrated decadmization process is 99.5%.

Example 2:

In a phosphoric acid solution having a composition of 50% P2O5, 6% solid, 3% sulfates and titrating 60 mgCd/KgP2O5, 83g of 98% sulfuric acid is introduced to reduce the sulfates to 8%. The temperature is maintained at 80°C.

After decantation of the decadmium acid, the cadmium content in the phosphoric acid is 3 mgCd/KgP2Os with a solid content of 0.5% and a sulfate content of 1%. The sludge after conditioning is recycled in the phosphate attack. The P2O5 yield of the integrated decadmization process is 99%.

Example 3:

Sludge rich in cadmium characterized by a temperature of 53°C, a P2O5 titer of 44%, a solid content of 20%, a sulfate content of 0.8% and a cadmium content of 85 ppm, are conditioned by mixing with phosphoric acid diluted in a ratio of 35 parts of phosphoric acid to one part of sludge (35/1 m/m), the phosphoric acid is supplied at a temperature of 65°C, a P2O5 titer of 28%, a solid content of 5%, a sulfate content of 2% and a cadmium content of 12 ppm. The sludge thus conditioned is characterized by a temperature of 47°C, a solid content of 6% by weight and a cadmium content of 56 ppm. They are then recycled in the phosphate attack reactor.

Claims (5)

1. Integrated process for decadmiation of phosphoric acid, comprising the following steps: attack (1) of phosphate (Ph) with sulfuric acid (AS) in a reactor so as to prepare a solution of phosphoric acid containing cadmium and calcium sulfate dihydrate or hemihydrate, concentration (2) of said solution of phosphoric acid, so as to form a concentrated phosphoric acid (PA) having a mass content between 42% and 61% in P2O5, preferably between 48% and 61%, addition (3) of sulfuric acid (AS) to concentrated phosphoric acid (PA) to adjust the free sulfate content in the mixture of sulfuric acid and phosphoric acid to a content of between 1.5% and 10% by weight of the mixture, preferably between 2.5 % and 9% by weight of the mixture, anhydrite being formed by recrystallization of calcium sulfate dihydrate and hemihydrate, cadmium co-crystallizing with said anhydrite, so as to obtain decadmium phosphoric acid and anhydrite sludge rich in cadmium, desulfation (4) of the decadmium phosphoric acid, in the presence of phosphate (Ph) to have in said phosphoric acid a solid content of between 1 and 15% by weight, preferably 7% by weight, and a sulfate level between 1% and 5% by weight, preferably 3% by weight; desupersaturation (5) and clarification (6) by decantation of the mixture of decadmium phosphoric acid and anhydrite sludge rich in cadmium, in order to separate the final phosphoric acid (Pli) having a cadmium content less than 10 ppm, or even less than 2 ppm, and the sludge rich in cadmium (Psi), conditioning (7) of said anhydrite sludge rich in cadmium (P _S i) with a solution of phosphoric acid (APd) having a mass titer less than or equal to 61% in P2O5, recycling of conditioned sludge (Ps2) in step (1) of attack of the phosphate (Ph) with sulfuric acid (AS). 2. Method according to claim 1, in which the decadmization (3) and desulfation (4) steps are carried out simultaneously. 3. Method according to claim 1, in which the decadmization (3) and desulfation (4) steps are carried out successively. 4. Process according to any one of the preceding claims, in which the decadmization of the phosphoric acid is carried out at a temperature between 50 and 120°C, preferably greater than 70°. 5. Method according to any one of the preceding claims, in which the decadmization of the phosphoric acid and the desulfation of the decadmified phosphoric acid are carried out in a single reactor. 6. Process according to any one of the preceding claims, in which the decadmization of the phosphoric acid is carried out at a pressure of between 10 ⁴ and 10 ⁵ Pa. 7. Method according to any one of the preceding claims, in which the step of conditioning the cadmium-rich anhydrite sludge (Psi) comprises an adjustment of the cadmium content, the P ₂ O ₅ content, the solid content, temperature and/or viscosity of said sludge. 8. Method according to any one of the preceding claims, in which, in the conditioning step, the anhydrite sludge rich in cadmium (Psi) has a temperature between 40 and 60°C, preferably equal to 50° C, and a solid content of between 5 and 25%, preferably equal to 10%. 9. Method according to any one of the preceding claims, in which, in the conditioning step, the phosphoric acid solution (APd) has a mass titer of less than 30% in P2O5, preferably less than 20% in P2O5 , and more preferably less than 10% in P2O5, 10. Method according to any one of the preceding claims, wherein, to mix the anhydrite sludge rich in cadmium (Psi) with the phosphoric acid solution (APd), said phosphoric acid solution (APd) is at a temperature greater than or equal to 40°C, preferably greater than 50°C, and more preferably greater than 60°C. 11. Method according to any one of the preceding claims, in which the conditioned sludge (Ps2) has a temperature of between 40 and 80°C, preferably equal to 47°C, and a solid content of between 5 and 20% by weight, preferably equal to 10%. 12. Method according to any one of the preceding claims, in which, during the recycling step, the conditioned sludge (Ps2) is introduced into the reactor for attacking the phosphate with sulfuric acid. 5 13. Method according to any one of the preceding claims, in which, during the recycling step, the conditioned sludge (Psz) is filtered with the calcium sulfate dihydrate or hemihydrate obtained by the reaction of attack of the phosphate by phosphoric acid.