JP2021172843A - Method for recovering rare metal - Google Patents

Abstract

To provide a method for recovering Sc in which the mixing of Th is reduced.SOLUTION: A method for recovering Sc includes the steps of: providing a solution containing Sc and Th; and subjecting the solution containing Sc and Th to solvent extraction. The step for providing the solution containing Sc and Th includes adding sulfate ions to the solution containing Sc and Th.SELECTED DRAWING: None

Description

The present invention relates to a rare metal recovery method. More specifically, the present invention relates to a method for recovering Sc, which is a kind of rare metal.

Titanium is purified from titanium ore by the Kroll process. In this Kroll process, titanium ore and coke are charged into the fluidized bed reactor, and chlorine gas is blown in from the bottom of the fluidized bed reactor. As a result, gaseous titanium tetrachloride is produced, which is recovered and reduced with magnesium or the like, and finally titanium sponge is produced.

However, titanium ore contains useful substances other than titanium. Patent Document 1 discloses a method for recovering Sc from a raw material containing Sc and Th. Further, Patent Document 1 discloses that a solid residue generated when a gas or liquid titanium tetrachloride is produced by reacting titanium ore with coke and chlorine gas is used as a raw material.

Patent Document 2 discloses that solvent extraction is performed on an aqueous phase containing Sc, and further, scrubbing is performed by adding an aqueous hydrochloric acid solution. Non-Patent Document 1 discloses scrubbing using sulfuric acid and hydrogen peroxide.

Japanese Unexamined Patent Publication No. 2018-150588 Japanese Unexamined Patent Publication No. 9-291320

A PROCESS Flowchart FOR THE EXTRACTION OF SCANDIUM FROM NIOCORP'S NIOBIUM SCANDIUM ELK CREEK DEPOSIT (Extraction 2018: Proceedings) Proceedings

From the viewpoint of industrial usefulness, it is desired to improve the purity when recovering Sc. In other words, it is desired to reduce the amount of impurities other than Sc. Th is one of the impurities when recovering Sc. This Th tends to behave similarly to Sc during solvent extraction with respect to Sc. Therefore, it has been difficult to reduce the contamination of Th, which is an impurity, when recovering Sc.

In view of the above problems, it is an object of the present invention to provide a method for recovering Sc with reduced Th mixing.

As a result of diligent studies by the present inventor, we focused on the process before solvent extraction. Specifically, we have found a new property that sulfate ions suppress the movement of Th from the aqueous phase to the oil phase and maintain Th in the aqueous phase. By applying this finding and adding sulfate ions before solvent extraction, Sc could be recovered while reducing Th contamination.

The present invention has been completed based on the above findings and includes the following inventions in one aspect.
(Invention 1)
Sc is a recovery method, and the above method is
A step of providing a solution containing Sc and Th,
A step of performing solvent extraction on the solution containing Sc and Th, and
Including
The step of providing the solution containing Sc and Th comprises adding sulfate ions to the solution containing Sc and Th.
Method.
(Invention 2)
The method of the present invention, wherein the addition of the sulfate ion comprises adjusting the pH with an acidic solution containing the sulfate ion.
Method.
(Invention 3)
A method according to the method 1 or 2, wherein the step of providing the solution containing Sc and Th includes the following.
-Leaching Sc and Th from a solid or slurry substance containing Sc and Th using hydrochloric acid.
-Perform solid-liquid separation to obtain a post-leaching liquid containing Sc and Th.
-Neutralizing the liquid after leaching and
-Solid-liquid separation is performed on the leached liquid after neutralization to obtain a solution containing Sc and Th.
(Invention 4)
The method according to any one of Inventions 1 to 3, wherein the solution containing Sc and Th is derived from a chloride residue generated when titanium tetrachloride is produced from titanium ore.
(Invention 5)
A method according to any one of Inventions 1 to 4, wherein the step of carrying out the solvent extraction includes using an organic phosphoric acid-based extractant as the extractant.
(Invention 6)
The method according to any one of Inventions 1 to 5.
The method further comprises the step of performing scrubbing on the oil phase of the solvent extraction.
The process of performing the scrubbing is
The first sub-step of scrubbing with a solution containing sulfuric acid,
After the first sub-step, a second sub-step in which scrubbing is performed with a solution containing hydrochloric acid, and
Including methods.
(Invention 7)
The method of invention 6
A method in which the sulfuric acid-containing solution of the first sub-step does not contain _{H 2} O _2.
(Invention 8)
The method of invention 7.
The method comprising the step of reusing the post-scrubbing liquid after scrubbing with a solution containing hydrochloric acid for leaching with the solution containing hydrochloric acid.

In one aspect, the method of the invention comprises adding sulfate ions to a solution containing Sc and Th. This makes it possible to reduce the movement of Th to the oil phase when Sc moves to the oil phase due to solvent extraction. Then, the purity of Sc can be improved.

Hereinafter, specific embodiments for carrying out the present invention will be described. The following description is for facilitating the understanding of the present invention. That is, it is not intended to limit the scope of the present invention.

1. 1. Overview In one embodiment, the present invention relates to a method for recovering Sc. The method comprises at least the following steps.
-Step of providing a solution containing Sc and Th-Step of performing solvent extraction for a solution containing Sc and Th Here, in a step of providing a solution containing Sc and Th, Sc and Th are used. Includes adding sulfate ions to the containing solution.
In the following, each step will be described in detail.

2. Step of providing a solution containing Sc and Th
2-1. Addition of Sulfate Ions As described above, the step of providing a solution containing Sc and Th includes adding sulfate ions to the solution containing Sc and Th. Here, the addition can be carried out in any embodiment, and is not limited to the form in which the powder containing sulfate ions is added to the solution containing Sc and Th and stirred. For example, a solution containing sulfate ions may be added to a solution containing Sc and Th, or vice versa.

The substance that supplies sulfate ions may be in a solid state or a liquid state. Further, examples of substances that supply sulfuric acid ions include sulfuric acid (H ₂ SO ₄ ) and sulfate. Examples of the sulfate include sodium sulfate, potassium sulfate, calcium sulfate and the like. Sulfate ions have the property of suppressing the movement of Th from the aqueous phase to the oil phase and maintaining Th in the aqueous phase during solvent extraction. Furthermore, the property is selective in relation to Sc. Specifically, sulfate ions have the property of suppressing the transfer of Th from the aqueous phase to the oil phase, while not inhibiting the transfer of Sc from the aqueous phase to the oil phase. This makes it possible to reduce the amount of Th mixed in Sc during solvent extraction.

Preferably, adding sulfate ions to a solution containing Sc and Th involves adjusting the pH with an acidic solution containing sulfate ions. The acidic solution containing sulfuric acid ion includes, for example, a combination of the above-mentioned sulfate salt and an acid (for example, hydrochloric acid), or sulfuric acid. Sulfuric acid is preferable from the viewpoint of simplicity of the components and the like.

The pH of the solution containing Sc and Th is adjusted to the acidic side by the acidic solution containing sulfate ions. As a result, Th tends to be stable in the state of being present as an ion in the aqueous phase. Then, due to this tendency, it is maintained in the aqueous phase during solvent extraction. Further, by adjusting to the acidic side, the generation of clad can be suppressed in the solvent extraction. The following description is not intended to limit the present invention, but it is presumed that there is the following relationship between pH and the generation of clad.
-First, when the pH is high, the amount of the extractant consumed by impurities (Fe, etc.) increases.
-This makes the extractant insufficient in terms of the amount of Sc.
-As a result, clad is generated.
-Therefore, the generation of clad can be suppressed by lowering the pH.

When adjusting the pH, the final target pH range is, but is not limited to, -1.0 to 1.0, preferably -0.5 to 0.5. It may be adjusted as follows.

2-2. Preparation of a solution containing Sc and Th A solution to which sulfate ions are added, that is, a solution containing Sc and Th can be prepared by any method. Typically, the solution containing Sc and Th may be derived from the chloride residue produced during the production of titanium tetrachloride from titanium ore.

Conventionally, titanium is generally purified from titanium ore by the Kroll process. As an example of the generation flow, titanium ore and coke are put into a fluidized bed reactor. Then, chlorine gas is blown in from the lower part of the fluidized bed reactor. Titanium ore reacts with chlorine gas to produce titanium tetrachloride. Titanium tetrachloride is in a gaseous state at the temperature inside the reactor. This gaseous titanium tetrachloride is sent to the next cooling system for cooling. The cooled titanium tetrachloride becomes liquid and is recovered.

When the gaseous titanium tetrachloride is sent to the next cooling system, the fine powder impurities are sent to the cooling system together with the air flow. The impurities include substances other than titanium (for example, Sc, Th, etc.), unreacted ore, unreacted coke, and the like. These impurities are recovered in solid form in the cooling system. In the present specification, this recovered product is referred to as a chloride residue. The chloride residue may be slurryed or in the form of a group of dry particles. Typically, a slurry can be used to recover Sc.

The solid substance or slurry contains Sc and Th, and Sc can be leached using hydrochloric acid. At this time, although it is not desirable, a part of Th is also leached together. The concentration of hydrochloric acid and other leaching conditions are not particularly limited, and known conditions may be adopted.

After leaching, solid-liquid separation can be performed to separate the residue from the leached liquid. A part of Sc and Th is distributed to the liquid side after leaching.

Neutralization can be performed on the leaching liquid after solid-liquid separation. A step of adjusting the pH to be more alkaline than at the time of leaching can be included. This allows Th to precipitate while leaving Sc in the solution.

The pH range in the neutralization step is not particularly limited, but is preferably 1.3 to 2.5. If it is less than 1.3, the precipitation of Th is unlikely to occur. On the other hand, when the pH exceeds 2.5, the amount of Th precipitation does not increase, but rather Sc also precipitates. A more preferred range is a pH of 1.8-2.3. This allows most Th to be precipitated without the Sc being lost due to precipitation.

In this way, solid-liquid separation is performed again on the leached liquid after neutralization. As a result, the precipitated Th is removed. On the liquid side, on the other hand, a solution containing Sc and Th can be obtained. In the above neutralization step, not all Th can be precipitated, and some Th remains dissolved in the solution together with Sc. Therefore, the solution obtained by solid-liquid separation after neutralization contains Th that could not be removed in addition to Sc.

Sulfate ions may be added to the solution containing Sc and Th thus obtained as described above.

3. 3. Solvent extraction As described above, after adding sulfate ions to the solution containing Sc and Th as described above, solvent extraction is performed. More specifically, solvent extraction is performed to move Sc to the oil phase side. Here, due to the effect of the sulfate ion described above, the amount of Th that moves to the oil phase side is reduced. This improves the purity of Sc.

The extractant to be used is not particularly limited, but may be, for example, an organic phosphoric acid-based extractant, specifically, D2EHPA (Di- (2-ethylhexyl) phosphoric acid) which is an acidic phosphoric acid ester, or The phosphonic acid ester may be 2-ethylhexyl 2-ethylhexyl phosphonic acid, or the phosphinic acid ester may be di (2,4,4'-trimethylpentyl) phosphoric acid.

The O / A ratio (volume ratio), which is the ratio of the oil phase to the aqueous phase, is also not particularly limited, but may be 1/10 to 1/2, preferably 1/6 to 1/4. It's okay. If the O / A ratio is increased, the generation of clad can be suppressed, but on the other hand, the amount of Th or the like distributed to the oil phase increases. If the O / A ratio is lowered, the amount of Th or the like distributed to the oil phase can be reduced, but on the other hand, the generation of clad becomes remarkable. Therefore, preferably, by adjusting the pH to the acidic side before the solvent extraction, the amount of Th or the like distributed to the oil phase can be reduced while suppressing the generation of clad.

4. Steps after solvent extraction (scrubbing)
After solvent extraction, Sc can be extracted from Sc that has moved to the oil phase by using known means (for example, Patent Documents 1 and 2).

However, it is preferable to carry out at least the following sub-steps instead of the above-mentioned known means or in addition to the above-mentioned known means.

4-1. First sub-step of scrubbing with a solution containing sulfuric acid Ideally, Sc is transferred to the oil phase by the above solvent extraction, while all Th stays on the aqueous phase side. However, in reality, a small amount of Th moves to the oil phase side. Therefore, it is preferable to further scrub to remove Th that has moved to the oil phase side.

Preferably, scrubbing can be performed in at least two steps. As the first sub-step, scrubbing can be carried out with a solution containing _{sulfuric acid (H 2} SO _4). Solutions containing sulfuric acid have a high selectivity for the effect of scrubbing on Th. That is, only Th can be selectively scrubbed without scrubbing for Sc. The concentration of sulfuric acid is not particularly limited and may be 0.5 mol / L to 5 mol / L, preferably 1 mol / L to 4 mol / L.

Preferably, the scrubbing solution containing sulfuric acid does not have to contain _{H 2} O _2. When the impurity concentration is high (for example, as shown in Non-Patent Document 1), the load in scrubbing becomes high. _{Therefore, H 2} O ₂ may be further added to assist the effect of sulfuric acid. However, in one embodiment, the present invention does not require _{H 2} O ₂ because the amount of impurities in the raw material is low in the first place.

4-2. Second sub-step of scrubbing with a solution containing hydrochloric acid After the first sub-step, scrubbing is carried out with a solution containing hydrochloric acid. As a result, other metal elements (for example, Fe) that have moved to the oil phase side can be scrubbed. The solution containing hydrochloric acid has a high selectivity of the scrubbing effect on Fe. That is, Sc can be selectively scrubbed only with Fe without being scrubbed. The concentration of hydrochloric acid is not particularly limited, and may be 3 mol / L to 5 mol / L, preferably 3.5 mol / L to 4.5 mol / L.

There are two important points regarding the above two sub-processes. The first important point is to combine the first sub-process and the second sub-process. In the scrubbing using sulfuric acid (first sub-step), the scrubbing effect on Th is excellent, but the scrubbing effect on Fe is inferior to the scrubbing effect using hydrochloric acid (second sub-step). On the other hand, in the scrubbing effect using hydrochloric acid (second sub-step), the scrubbing effect on Fe is excellent. However, although a scrubbing effect on Th can be obtained to some extent, it is inferior to scrubbing using sulfuric acid (first sub-step). Therefore, by combining both, it is possible to make up for each other's shortcomings.

The second important point is that the second sub-process is performed after the first sub-process. The composition of the scrubbing liquid using hydrochloric acid in the second sub-step is the same as or similar to that of the leachate using hydrochloric acid. Therefore, the liquid after scrubbing in the second sub-step (post-scrubbing liquid) may be reused for the leaching reaction using hydrochloric acid.

If the second sub-step is performed without performing the first sub-step (or the order is changed), the following events may occur. Th is contained in the oil phase to be scrubbed, and a certain amount of Th is contained in the post-scrubbing liquid together with Fe by the second sub-step. Since Th is a generally repellent substance, these post-scrubbing liquids may not be suitable for reuse.

Therefore, by performing the second sub-step after the first sub-step, the degree to which Th is contained in the liquid after scrubbing in the second sub-step can be reduced. This is because Th has already been scrubbed from the oil phase by the first sub-step.

By carrying out the above two sub-steps, an oil phase in which Th is scrubbed and Sc is contained can be obtained.

5. Steps after solvent extraction (steps after scrubbing)
After the scrubbing, Sc can be recovered by using known means (Patent Documents 1 and 2). For example, crystallization peeling can be performed with an alkaline aqueous solution such as NaOH to obtain a scandium hydroxide slurry, and the scandium hydroxide slurry can be filtered and calcined, and finally recovered in the form of _{Sc 2} O _3. Alternatively, the obtained Sc (OH) ₃ can be leached, and scandium can be precipitated in the form of scandium carboxylic acid using a carboxylic acid such as oxalic acid, further calcined, and recovered in the form of _{Sc 2} O _3. can.

Hereinafter, in order to promote understanding of the present invention, more specific examples will be disclosed.

Chloride residue is a substance recovered as a solid substance in a furnace for recovering titanium tetrachloride volatilized in titanium smelting. The chloride residue was obtained from Toho Titanium Co., Ltd. Further, the chloride residue was in a slurry state after being washed with water.

Alkaline melting-ICP emission spectroscopic analysis was used for analysis of the amounts of Sc, Th, and Fe in slurries, solids, and solutions (ICP-AES, manufactured by Seiko Instruments Inc., SPS7700).

The above-mentioned slurry was leached with hydrochloric acid, and solid-liquid separation was performed to obtain a liquid after leaching. The leachate was neutralized and then solid-liquid separated to obtain a solution containing Sc and the like.

6. Example (solvent extraction before scrubbing)
Sulfuric acid or hydrochloric acid was added to the solution containing Sc and the like. The final concentration of sulfuric acid or hydrochloric acid added was set to the concentration shown in Table 1. Then, an organic solvent containing 7.5% of D2EHPA and 3% of TBP as a modifier was added so that the O / A ratio (volume ratio) was 1/5. Then, Sc, Th, and Fe remaining on the aqueous phase side were measured, and the extraction rate (the amount distributed to the oil phase side with respect to the amount originally present on the aqueous phase side) was calculated.
The results are shown in Table 1.

In each of the above Experimental Examples 1 to 4, Sc was extracted 100% on the oil phase side. However, referring to Experimental Example 4, when hydrochloric acid was added, not only Sc but also Th was extracted to the oil phase side at the same extraction rate. However, referring to Experimental Examples 2 and 3, when sulfuric acid was added, the extraction rate of Sc could be achieved at 100%, while the extraction rate of Th could be suppressed. This difference in Th extraction rate cannot be explained simply by the effect of adjusting the pH. This is because, in Experimental Example 4, the pH is adjusted to the same level as in Experimental Example 2. However, in Experimental Example 2, the effect of suppressing the Th extraction rate is superior to that of Experimental Example 4. Therefore, it was shown that the effect of suppressing the extraction rate of Th is due to the sulfate ion, not the hydrogen ion of the sulfuric acid. Further, in Experimental Example 3, it was shown that the effect of suppressing the extraction rate of Th increases as the sulfate ion concentration increases.

Further, in Experimental Example 1, the generation of clad was observed, but on the other hand, it was not observed in Experimental Examples 2 to 4. Further, as a modification of Experimental Example 1, an experiment in which the O / A ratio was changed to 1 / 5.7 (Experimental Example 1A) and an experiment in which the O / A ratio was changed to 1 / 3.5 (Experimental Example 1B). Was carried out. In Experimental Example 1A, the extraction rate of Th could be suppressed as compared with Experimental Example 1, but clad was generated. On the other hand, in Experimental Example 1B, no clad was observed as compared with Experimental Example 1, but the extraction rate of Th was equivalent to that in Example 1. As described above, it is shown that the addition of sulfuric acid can reduce the O / A ratio while preventing the generation of clad, and has the effect of suppressing the extraction rate of Th by lowering the O / A ratio. Was done.

実験例５〜６を参照すると、塩酸を含むスクラビング液では、Ｔｈをある程度スクラビングするものの、Ｆｅをより顕著にスクラビングする傾向が見られた。一方で、実験例７〜９を参照すると、硫酸を含むスクラビング液では、Ｆｅをある程度スクラビングするものの、Ｔｈをより顕著にスクラビングする傾向が見られた。また、実験例５〜９において、塩酸及び硫酸のいずれも、Ｓｃのスクラビングには大きく影響しなかった。実験例１０を参照すると、Ｔｈ及びＦｅいずれに対してもスクラビング効果を示すものの、選択性は見られなかった。 7. Example (removal of Th etc. by scrubbing)
The oil phase containing Sc was scrubbed under the conditions shown in Table 2. The O / A ratio (volume ratio) was 1/1. The scrubbing rate was calculated by dividing the concentration of each element in the organic phase after scrubbing by the concentration of each element in the organic phase before scrubbing.

With reference to Experimental Examples 5 to 6, in the scrubbing solution containing hydrochloric acid, Th was scrubbed to some extent, but Fe tended to be scrubbed more remarkably. On the other hand, referring to Experimental Examples 7 to 9, in the scrubbing solution containing sulfuric acid, although Fe was scrubbed to some extent, Th tended to be scrubbed more remarkably. Further, in Experimental Examples 5 to 9, neither hydrochloric acid nor sulfuric acid had a significant effect on the scrubbing of Sc. With reference to Experimental Example 10, although a scrubbing effect was exhibited for both Th and Fe, no selectivity was observed.

From the above, it was shown that the amount of Th contained in the post-scrubbing liquid containing hydrochloric acid can be reduced by treating with the scrubbing liquid containing sulfuric acid before treating with the scrubbing liquid containing hydrochloric acid. Therefore, it was shown that the post-scrubbing liquid containing hydrochloric acid can be reused in the leaching step and the like.

8. Example (combination of scrubbing)
Further, for the purpose of confirming the effect when both scrubbing are combined, a step of treating with a scrubbing solution containing sulfuric acid and a step of treating with a scrubbing solution containing hydrochloric acid after the step were carried out in combination. Specifically, scrubbing with sulfuric acid 1 mol / L and an O / A ratio of 1/1 was carried out in one step, and then scrubbing with hydrochloric acid 4 mol / l and an O / A ratio of 1/4 was carried out in four steps in a countercurrent manner. carried out. As a result, the scrubbing rate of Sc was 0.0%, the scrubbing rate of Th was 99.6%, and the scrubbing rate of Fe was 99.8%.

Therefore, by combining both scrubbing, a good scrubbing rate could be achieved for both Th and Fe.

9. Example (Grade of Sc (OH) ₃ obtained by a combination of scrubbing)
In addition, an experiment was conducted to compare the quality of _{Sc (OH) 3} finally obtained between the case where two scrubbing was combined and the case where only the conventional one-step scrubbing was performed. In the case of combining two scrubbing, scrubbing is carried out under the conditions described in "8. Example (combination of scrubbing)" above, and then back extraction is performed with 2M NaOH to obtain _{a Sc (OH) 3 slurry.} rice field. In the comparison target, as one-step scrubbing, scrubbing with hydrochloric acid 4 mol / l and O / A ratio 1/4 was carried out in four steps in a countercurrent direction, and then back extraction was carried out with 2 M NaOH, and Sc (OH) ₃ slurry was performed. Got

For each slurry, the grades of Sc, Th, and Fe were measured, and the Th / Sc ratio (mg ratio) and the Fe / Sc ratio (mg ratio) were calculated. In the comparison target, the Th / Sc ratio was 6.3 × 10 ^-3 , and the Fe / Sc ratio was 1.3 × 10 ^-3 .

On the other hand, when scrubbing was combined, the Th / Sc ratio was 1.3 × 10 ^-4 and the Fe / Sc ratio was 1.3 × 10 ^-4 .

Therefore, it was shown that the combination of scrubbing improves the purity of Sc.

The specific embodiments of the present invention have been described above. The above-described embodiment is merely a specific example of the present invention, and the present invention is not limited to the above-described embodiment. For example, the technical features disclosed in one of the above embodiments can be applied to other embodiments. Further, unless otherwise specified, for a specific method, it is possible to replace some steps with the order of other steps, and an additional step may be added between the two specific steps. The scope of the present invention is defined by the claims.

Claims (8)

Sc is a recovery method, and the above method is
A step of providing a solution containing Sc and Th,
A step of performing solvent extraction on the solution containing Sc and Th, and
Including
The step of providing the solution containing Sc and Th comprises adding sulfate ions to the solution containing Sc and Th.
Method. The method of claim 1, wherein adding the sulfate ion comprises adjusting the pH with an acidic solution containing the sulfate ion.
Method. The method according to claim 1 or 2, wherein the step of providing the solution containing Sc and Th includes the following.
-Leaching Sc and Th from a solid or slurry substance containing Sc and Th using hydrochloric acid.
-Perform solid-liquid separation to obtain a post-leaching liquid containing Sc and Th.
-Neutralizing the liquid after leaching and
-Solid-liquid separation is performed on the leached liquid after neutralization to obtain a solution containing Sc and Th. The method according to any one of claims 1 to 3, wherein the solution containing Sc and Th is derived from a chloride residue generated when titanium tetrachloride is produced from titanium ore. The method according to any one of claims 1 to 4, wherein the step of carrying out the solvent extraction includes using an organic phosphoric acid-based extractant as the extractant. The method according to any one of claims 1 to 5.
The method further comprises the step of performing scrubbing on the oil phase of the solvent extraction.
The process of performing the scrubbing is
The first sub-step of scrubbing with a solution containing sulfuric acid,
After the first sub-step, a second sub-step in which scrubbing is performed with a solution containing hydrochloric acid, and
Including methods. The method of claim 6
A method in which the sulfuric acid-containing solution of the first sub-step does not contain _{H 2} O _2. The method of claim 7.
The method comprising the step of reusing the post-scrubbing liquid after scrubbing with a solution containing hydrochloric acid for leaching with the solution containing hydrochloric acid.