JP2008142650A - Method for removing selenium from selenate-containing liquid - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for removing selenium from a selenate-containing liquid produced in metal refining by adding a reducing agent, in which selenium in the liquid is removed to a concentration of less than 1 mg/L with an inexpensive reducing agent in a cost-effective and efficient manner. <P>SOLUTION: This method comprises the addition of a reducing agent to a selenate-containing liquid produced in metal refining in the coexistence of copper ions to remove selenium in the liquid. The method is characterized in that the content of copper ions in the selenate-containing liquid is regulated to 5 or more in terms of the molar ratio to selenium in the liquid, an alkali sulfite waste liquid produced as a by-product produced in a sulfuric acid production process in a smelting waste gas containing a sulfurous gas is then added to the copper ion-containing selenate-containing liquid to prepare a mixed liquid, and the resultant precipitates containing copper (I) selenide are then separated. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a method for removing selenium from a selenic acid-containing liquid, and more specifically, a selenium-containing liquid generated in metal smelting is added with a reducing agent in the presence of copper to separate and remove selenium in the liquid. The present invention relates to a method for economically and efficiently removing selenium in a liquid to a concentration of less than 1 mg / L using an inexpensive reducing agent.

In metal smelting using raw ore containing as a main component a sulfide mineral such as copper, nickel, lead, etc., as in the smelting of copper, nickel, lead, etc., selenium is included in the intermediate generated from the process. In many cases, (Se) is contained. This is because the sulfide mineral usually contains selenium, and the selenium contained in the raw material ore is volatilized and concentrated in smoke ash by various methods of the smelting process, or This is because it is distributed in the intermediate in the smelting process in various forms such as being dissolved and concentrated in the leachate or electrolyte.
On the other hand, the intermediates generated in the smelting process contain a lot of various valuable metals. From the standpoint of effective use of resources and prevention of pollution, it is not possible to recover valuable metals in these intermediates. It is important for smelters.

  As described above, when recovering valuable metals from intermediates generated in metal smelting, various methods are used according to the characteristics of the valuable metals. For example, in the leaching method used as a general recovery method when the intermediate is in a solid state, when the intermediate contains selenium, the obtained leachate contains selenium together with valuable metals. It comes to be. Also, when recovering valuable metals by a dry method other than the leaching method, waste liquid is generated in the final process, and in most cases, selenium is contained in the waste liquid. The removal and separation of selenium contained in such a leachate or waste solution is important from the viewpoint of reducing impurities in the valuable metal and preventing pollution, as well as recovering the valuable metal in the intermediate.

The selenium contained in the leachate or waste liquid is mainly dissolved in the form of selenite ion (SeO ₃ ²⁻ ) or selenate ion (SeO ₄ ²⁻ ). As means for removing these selenium from the liquid, conventionally, an adsorption method in which selenium is adsorbed and separated using a chelate resin (see, for example, Patent Document 1), and selenate is reduced using ferrous iron. There are known reduction methods (see, for example, Patent Document 2).
However, the above adsorption method is not a fundamental separation method because selenium is dissolved again in the waste liquid during regeneration (elution) of the adsorbent and the waste liquid containing selenium needs to be treated again. In the above reduction method, selenite ions contained in the solution are relatively easily reduced and separated from the solution. On the other hand, selenate ions are usually obtained because the reaction rate is slow. In order to reduce the residual selenium concentration, for example, selenium in the liquid to a concentration of less than 1 mg / L, excessive chemical addition or a long-time treatment is required, which is disadvantageous both economically and efficiently. Moreover, when the wet method is adopted as a method for recovering valuable metals, the selenate ion abundance ratio is often higher than the selenite ion depending on the leaching conditions. There was a problem that became difficult.

  As this solution, for example, 0.2 mol or more of divalent copper ions is added to an aqueous solution containing selenium to increase the reaction rate, and then sufficient to reduce selenate. A method for reducing and separating selenium by adding a reducing agent having a reducing power (for example, see Patent Document 3) is disclosed. In this method, the coexisting copper ions are said to play a role of reducing the activation energy of the reduction reaction of selenic acid, and selenium can be separated efficiently. However, in this method, it is indispensable to add a reducing agent such as sulfurous acid gas, sulfite, metallic iron, metallic cadmium, metallic aluminum in addition to copper ions. There was a general problem.

  In addition, a method of reducing and recovering selenium by blowing a sulfurous acid gas diluted to 8 to 12% by weight as air as a reducing agent into an aqueous selenium solution in which chlorine ions coexist (see, for example, Patent Document 4). Has been. Even in this method, since a relatively high concentration of sulfurous acid gas is used, there is an economical problem that a great amount of reducing agent costs are generated.

  In order to solve such economic problems, sulfur dioxide is contained as a sulfurous acid or sulfurous acid gas source at a concentration of about 15% by weight discharged from the smelting process of metals such as copper, nickel and lead. It is conceivable to use existing smelting exhaust gas. However, this smelting exhaust gas has a high temperature and contains impurities such as heavy metal fume, and cannot be used directly for preventing the dispersion of impurities into the system. Normally, this smelting exhaust gas is used as a raw material for producing sulfuric acid in a sulfuric acid production process having functions such as gas cleaning, cooling and gas absorption. Therefore, in order to directly use smelting exhaust gas as a reducing agent for selenium separation, a separate facility from existing facilities is required, and the demand for selenium reduction cannot be expected if the demand for sulfuric acid increases. To do. As described above, the method using the smelting exhaust gas has a problem that it is difficult to use industrially in the actual operation of metal smelting, such as requiring a large processing facility. Therefore, there has been a demand for a method for economically and efficiently removing selenium from a selenic acid-containing liquid generated in metal smelting using an inexpensive reducing agent.

Japanese Patent No. 3586165 (first page, second page) JP 2001-9467 (first page, second page) JP-A-7-215703 (first page, second page) Japanese Patent No. 3616314 (first page, second page)

  In view of the above-mentioned problems of the prior art, an object of the present invention is to provide a method for removing selenium in a liquid by adding a reducing agent in the presence of copper from a selenic acid-containing liquid generated in metal smelting. An object of the present invention is to provide a method for economically and efficiently removing selenium contained therein at a concentration of less than 1 mg / L using an inexpensive reducing agent.

  In order to achieve the above-mentioned object, the present inventors have conducted intensive research on a method for removing selenium in a liquid by adding a reducing agent in the presence of copper to a selenic acid-containing liquid produced in metal smelting. As a result of overlapping, after adjusting the copper ion content ratio in the selenate-containing liquid to a specific value, as a reducing agent, using an alkali sulfite waste liquor by-produced in the sulfuric acid production process of the smelting exhaust gas containing sulfite gas, It has been found that selenium in the liquid can be efficiently removed to a concentration of less than 1 mg / L, and the present invention has been completed. In addition, the said alkali sulfite waste liquid was the waste generated from metal smelting, such as copper, nickel, lead.

That is, according to the first invention of the present invention, in the method for removing selenium in the liquid by adding a reducing agent to the selenic acid-containing liquid produced in metal smelting in the presence of copper ions,
Adjusting the copper ion content ratio of the selenic acid-containing liquid to 5 or more in molar ratio with respect to selenium in the liquid, and then sulfuric acid of a smelting exhaust gas containing sulfite gas in the obtained selenic acid-containing liquid containing copper ions A method for removing selenium from a selenate-containing liquid, characterized in that an alkali sulfite waste liquor produced as a by-product in a production process is added to form a mixed liquid, and then a precipitate containing copper (I) selenide is separated. Is provided.

  Moreover, according to 2nd invention of this invention, when adjusting the copper ion concentration of the said selenate-containing liquid in 1st invention, the aqueous solution containing the copper ion produced in metal smelting as a copper ion source A method for removing selenium from a selenate-containing liquid is provided.

  According to a third aspect of the present invention, in the first aspect, the selenate-containing liquid is an aqueous solution containing copper ions produced from a step of purifying a noble metal element from anode slime. A method for removing selenium from a selenate-containing liquid is provided.

  According to a fourth aspect of the present invention, in the first aspect, the alkali sulfite waste liquid is a residual liquid after first used as a leachate for dissolving silver in the step of purifying the noble metal element from the anode slime. A method for removing selenium from a selenate-containing liquid is provided.

  According to a fifth aspect of the present invention, from the selenic acid-containing liquid according to the first aspect, the acid concentration of the mixed liquid is adjusted to 1.5 to 3.0 mol / L. A method for removing selenium is provided.

  According to a sixth aspect of the present invention, there is provided a method for removing selenium from a selenate-containing liquid, characterized in that, in the first aspect, the temperature of the mixed liquid is adjusted to 60 to 80 ° C. The

  The method for removing selenium from the selenic acid-containing liquid of the present invention is a method for removing selenium exhaust gas containing sulfur dioxide gas as a reducing agent, up to a concentration of less than 1 mg / L of selenium in a selenic acid-containing liquid generated in metal smelting. Since it can be separated and removed economically and efficiently by using alkali sulfite waste liquor by-produced in the sulfuric acid production process, its industrial value is extremely large. In the above method, selenium can be separated and removed by a simple means of first adjusting the copper ion content ratio of the selenate-containing liquid, then adding the alkali sulfite waste liquid to this, and mixing and stirring. It is efficient and economical because it does not require any additional special equipment for gas-liquid mixing required when sulfurous acid gas is used, and other reducing agents other than alkali sulfite waste liquid. Is also advantageous.

Hereinafter, the method for removing selenium from the selenate-containing liquid of the present invention will be described in detail.
The method for removing selenium from the selenic acid-containing liquid of the present invention is a method of removing selenium in the liquid by adding a reducing agent to the selenic acid-containing liquid produced in metal smelting in the presence of copper ions. Adjusting the copper ion content ratio of the selenic acid-containing liquid to 5 or more in molar ratio with respect to selenium in the liquid, and then sulfuric acid of a smelting exhaust gas containing sulfite gas in the obtained selenic acid-containing liquid containing copper ions An alkaline sulfite waste liquor produced as a by-product in the production process is added to form a mixed solution, and then the resulting precipitate containing copper (I) selenide is separated.

In the present invention, a selenic acid-containing liquid generated in metal smelting contains a predetermined amount of copper ions, and then, as a reducing agent, an alkali sulfite waste liquor by-produced in a sulfuric acid production process of smelting exhaust gas containing sulfurous acid gas. It is important to add to form a mixture to produce copper (I) selenide. Thereby, economical efficiency improves by utilizing the waste sulfite alkali waste liquid by-produced in the sulfuric acid manufacturing process of the smelting exhaust gas containing sulfurous acid gas which was a waste in metal smelting as a reducing agent. Moreover, by adjusting the copper ion content ratio to 5 or more by molar ratio with respect to selenium in the liquid, selenium can be efficiently separated and removed as a precipitate containing copper (I) selenide (Cu ₂ Se). it can.

  That is, in the above method, by mixing the selenate-containing liquid with copper ions and alkali sulfite waste liquid, selenate is reduced to selenious acid and further into a metallic state without the need for other additives, At the same time, usually divalent copper ions are reduced to a monovalent state to produce and precipitate copper (I) selenide. Copper ions are presumed to have an effect of reducing the activation energy of the reduction reaction in which selenic acid is reduced to selenious acid, and the copper metal produced by reduction of copper ions is very fine Therefore, it is considered that it reacts efficiently with selenic acid and selenious acid to produce copper (I) selenide. That is, the reaction is more likely to proceed thermodynamically when selenium ions are precipitated as copper (I) selenide rather than being reduced to a metallic state alone.

  In the above method, for example, a first step of adjusting the copper ion content ratio of the selenate-containing liquid, then a second step of adding an alkali sulfite waste liquid to form a mixed solution, and finally mixing for a predetermined time After stirring, selenium can be separated and removed by a simple means consisting of the third step of separating the precipitate containing copper (I) selenide produced, which is efficient and necessary when using gas. No new special equipment for gas-liquid mixing is required.

In the said 1st process, the copper ion content rate of a selenic acid containing liquid is adjusted to 5 or more by molar ratio with respect to the selenium in this liquid, Preferably it is 5-10. That is, in order to precipitate selenium ions as copper (I) selenide, two equivalents of copper ions are theoretically sufficient with respect to selenium ions, but in practice, the copper ion content is in the liquid. If the molar ratio of the selenium is less than 5, it is difficult to make the residual selenium concentration after selenium removal less than 1 mg / L. In addition, since copper ions existing in a divalent state are usually reduced to a monovalent state and further to a metal state, alkali sulfite waste liquid is consumed. Therefore, when a copper ion source is newly added, 10 or less. To be elected.
On the other hand, there is no particular upper limit of the copper ion content that inhibits the separation and removal of selenium, but the copper ion concentration in the liquid is preferably less than 100 g / L. That is, an aqueous solution having a copper ion concentration of 100 g / L or more in the liquid is difficult to obtain from the copper or noble metal element purification step, and a special apparatus is required separately to achieve this concentration or more. This is disadvantageous in terms of cost.

  Here, the method for adjusting the copper ion content ratio of the selenate-containing liquid is not particularly limited, and a predetermined amount of copper ion source, for example, a soluble copper salt or copper ion is added to the selenate-containing liquid. What is necessary is just to add and mix the aqueous solution containing. For example, an aqueous solution containing a predetermined amount of a soluble copper salt or copper ion in a selenate-containing liquid is added, and a general stirring method such as a method using a stirring bar, a method using a handy stirrer, or aeration is appropriately used. Select and stir.

  In metal smelting of copper, nickel, lead, etc., an aqueous solution containing copper ions is generated in the copper or noble metal element refining step, and the amount is sufficiently larger than the amount of selenate-containing liquid generated. . Therefore, it is particularly advantageous to use a predetermined amount of the aqueous solution containing copper ions because a cost for newly preparing an aqueous solution containing copper ions does not occur. For example, since a predetermined amount of copper ions is already contained in a selenate-containing liquid produced from a process of purifying a noble metal element from anode slime by a wet method, it is not particularly necessary to add new copper ions.

  In the second step, an alkali sulfite waste liquid is added to a selenate-containing liquid containing copper ions to form a mixed liquid. Thereafter, in the third step, after mixing and stirring for a predetermined time, the produced precipitate containing copper (I) selenide is separated.

As the alkali sulfite waste liquid used in the above method, one produced as a by-product in the sulfuric acid production process of the smelting exhaust gas containing sulfurous acid gas is used. Although it does not specifically limit as the manufacturing method, For example, it is as follows.
In the smelting process of metal smelting using sulfide minerals as the raw ore, there is a process to raise the quality of the target metal by oxidizing and removing sulfur components in the ore. And becomes the main component of smelting exhaust gas. Concentrated sulfuric acid is produced from this smelting exhaust gas in the sulfuric acid production process. Here, the sulfurous acid gas in the smelting exhaust gas is absorbed in an absorbing solution such as dilute sulfuric acid. The exhaust gas containing sulfurous acid gas that could not be absorbed in the sulfuric acid production process is sent to the exhaust gas treatment process. In this exhaust gas treatment process, an alkali metal hydroxide and / or a method which is economically advantageous because the sulfur dioxide gas concentration in the exhaust gas released to the atmosphere for pollution prevention conforms to the regulatory standards, and the treatment cost is low and economical. A method in which sulfurous acid gas is absorbed in an aqueous solution of an alkali metal carbonate is used. At this time, alkali sulfite waste liquid is generated.
The composition of the alkali sulfite waste liquors, for example, SO ₂ is 20~130g / L, and Na are 15~90g / L. In addition, this alkali sulfite waste liquor was normally not oxidized because it was detoxified by acidification or acid decomposition.

  As a method of using the alkali sulfite waste liquid, it can be used as it is as a reducing agent for separating and removing selenium from the selenate-containing liquid, but practically, in the step of purifying the noble metal element from the anode slime, It is more economically advantageous for the whole process to use the residual liquid after being used as a leachate for dissolving silver as a reducing agent for removing selenium from the selenate-containing liquid. That is, some of the sulfite ions in the alkali sulfite waste liquid are consumed in the silver extraction reaction, but most of the sulfite ions remain as sulfite ions in the residual liquid after the silver extraction. It can be used as a reducing agent.

As the addition amount of the alkali sulfite waste liquid to the selenate-containing liquid, SO ₂ can be sufficiently reduced by the amount of selenate contained in the selenate-containing liquid and the amount of added copper ions. Adjusted to be able to.

In the third step, as a mixing method, for example, a container in which a selenic acid-containing liquid containing copper ions is retained is used as a reaction tank, and the alkali sulfite waste liquid is mixed and stirred in the reaction tank. Thereby, selenium in the selenic acid-containing liquid is reduced and precipitated as copper (I) selenide, so that it can be easily separated and removed. Here, as a method of mixing and stirring, a general method is used as in the first step described above.
When the alkali sulfite waste liquid is mixed and stirred, the sulfite in the liquid is decomposed and sulfite gas having a concentration of approximately 100% is generated. This sulfurous acid gas acts as a direct reducing agent in the reduction reaction. At this time, the sulfurous acid gas that has not contributed to the reduction reaction is discharged out of the reaction system, but is sucked and recovered by the exhaust gas collection facility.

It does not specifically limit as acid (H ^<+> ) density | concentration of the said liquid mixture, It is preferable to adjust to 1.5-3.0 mol / L. That is, when the acid concentration is less than 1.5 mol / L, the reduction reaction of selenium is slow, which is disadvantageous efficiently. On the other hand, when the acid concentration exceeds 3.0 mol / L, the amount of acid added such as sulfuric acid or hydrochloric acid increases, which is economically disadvantageous, and further, the cost of wastewater treatment increases.
When the acid concentration in the mixed solution is 1.5 mol / L or more, the pH is 1 or less. In this case, almost all the sulfite is decomposed into sulfurous acid gas, so that the reduction reaction proceeds reliably.

The influence of the acid concentration and time will be described with reference to the drawings.
Here, as the selenic acid-containing liquid, those generated in actual operation in the precious metal refining process of a copper smelting factory (selenium: 0.1 to 1 g / L, copper: 10 to 20 g / L), and alkali sulfite waste liquid A sodium sulfite aqueous solution (Na ₂ SO ₃ concentration: 200 g / L), which is a waste solution of the silver purification process, was used. At this time, the acid concentration is 1.0 to 1.5 mol / L, 1.5 to 2.0 mol / L, 2.0 to 2.5 mol / L, and 2.5 mol / L or more. FIG. 1 shows the result of determining the residual selenium concentration in the liquid after completion of the reaction by changing the stirring time up to 600 minutes at the maximum at a temperature of 80 ° C. of the mixed liquid.

  From FIG. 1, when the acid concentration is less than 1.5 mol / L, selenium remains at 10 mg / L or more even if the stirring time (reaction time) is extended to 400 minutes or more. Therefore, it can be seen that the acid concentration is preferably 1.5 mol / L or more in order to make the residual selenium concentration less than 1 mg / L. At this time, if the acid concentration is 1.5 mol / L or more, it is found that the necessary stirring time is about 300 minutes.

  The temperature of the liquid mixture is not particularly limited and is preferably 60 to 90 ° C. That is, when the temperature is lower than 60 ° C., it takes time for the reduction reaction, which is disadvantageous efficiently. On the other hand, when the temperature exceeds 90 ° C., the material of the reaction vessel and the temperature raising equipment are limited, and the capital investment cost increases, which is economically disadvantageous.

  As described above, according to the method of the present invention, selenium is reduced from a selenate-containing liquid generated in metal smelting using an alkaline sulfite waste liquor by-produced in a sulfuric acid production process of smelting exhaust gas containing sulfite gas, In the separation, the selenium concentration in the liquid after the treatment can be reliably reduced to less than 1 mg / L in a reaction time of about 300 minutes. The obtained precipitate containing copper (I) selenide is circulated and used in the smelting process of copper smelting and the like.

  Hereinafter, the present invention will be described in more detail with reference to Examples and Comparative Examples of the present invention, but the present invention is not limited to these Examples. The metal analysis method used in Examples and Comparative Examples is ICP emission analysis or fluorescent X-ray quantitative analysis.

(Examples 1-4)
As the selenate-containing liquid, the liquids (a) to (d) (Examples 1 to 4) shown in Table 1 generated in actual operation in the precious metal refining process of the copper smelting factory were used. Table 1 shows the compositions of the selenate-containing liquids (a) to (d). In addition, the acid (H ⁺ ) density | concentration of these liquids was 2-3 mol / L in all.
To 500 mL of each of the liquids (a) to (d), 500 mL of an aqueous sodium sulfite solution (Na ₂ SO ₃ concentration: 200 g / L), which is the residual liquid of the silver purification step, is added as an alkali sulfite waste liquid to obtain a mixed solution. It was. The mixture was heated to 80 ° C. and stirred for 3 hours, followed by solid-liquid separation, and the obtained filtrate was analyzed for selenium and copper. The results are shown in Table 2.

  From Table 2, in Examples 1-4, the smelting exhaust gas containing sulfurous acid gas from the selenic acid-containing liquid produced in metal smelting in which the copper ion content ratio is 5 or more in terms of molar ratio to selenium in the liquid. It can be seen that the selenium concentration in the treated liquid can be reliably reduced to less than 1 mg / L when selenium is reduced and separated using the alkali sulfite waste liquor produced as a by-product in the sulfuric acid production process.

(Comparative Example 1)
As the selenic acid-containing liquid, except that a selenium concentration of 1.2 g / L and a copper concentration of 1.7 g / L were prepared, the selenium and copper of the obtained filtrate were analyzed in the same manner as in Example 1. .
As a result, in Comparative Example 1, since the Cu / Se molar ratio is 1.8 and the content of copper ions does not meet the conditions of the present invention, the selenium concentration in the filtrate is 0.049 g / L, It can be seen that the removal of selenium is insufficient.

  As is clear from the above, the method for removing selenium from the selenate-containing liquid of the present invention is effectively used as a method for removing selenium contained in various industrial waste liquids, and in particular, a smelting method for copper, nickel, lead, etc. It is suitably used for the treatment of waste liquid containing selenic acid produced from the valuable substance separation and purification process from the anode slime generated in the electrolytic purification process.

Stirring was carried out with four acid concentrations of 1.0 to 1.5 mol / L, 1.5 to 2.0 mol / L, 2.0 to 2.5 mol / L, and 2.5 mol / L or more. It is a figure showing the result of having changed time and calculating | requiring the residual selenium density | concentration in the liquid after completion | finish of reaction.

Claims (6)

In the method of removing selenium in the liquid by adding a reducing agent to the selenic acid-containing liquid produced in metal smelting in the presence of copper ions,
Adjusting the copper ion content ratio of the selenic acid-containing liquid to 5 or more in molar ratio with respect to selenium in the liquid, and then sulfuric acid of a smelting exhaust gas containing sulfite gas in the obtained selenic acid-containing liquid containing copper ions A method for removing selenium from a selenate-containing liquid, characterized in that an alkali sulfite waste liquor produced as a by-product in a production process is added to form a mixed liquid, and then a precipitate containing copper (I) selenide is separated. .   When adjusting the copper ion concentration of the selenic acid-containing liquid, an aqueous solution containing copper ions produced in metal smelting is added as a copper ion source. How to remove selenium.   The method for removing selenium from a selenate-containing liquid according to claim 1, wherein the selenate-containing liquid is an aqueous solution containing copper ions produced from the step of purifying a noble metal element from anode slime.   2. The selenium-containing liquid according to claim 1, wherein the alkali sulfite waste liquid uses a residual liquid after being used as a leachate for dissolving silver in a step of purifying a noble metal element from anode slime. Removal method.   The method for removing selenium from a selenate-containing liquid according to claim 1, wherein the acid concentration of the mixed solution is adjusted to 1.5 to 3.0 mol / L.   The temperature of the said liquid mixture is adjusted to 60-80 degreeC, The removal method of selenium from the selenic-acid containing liquid of Claim 1 characterized by the above-mentioned.

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