KR20230116293A - Method for producing lithium hydroxide using lithium sulfate and barium oxide - Google Patents

Abstract

The present invention relates to a method for producing lithium hydroxide, and more specifically, by using a low-purity lithium sulfate solution, the process is simple and economical compared to the prior art, energy efficiency is improved, and lithium hydroxide can be produced in an environmentally friendly way because there is no waste generation. It is a method for producing lithium hydroxide using lithium sulfate and barium oxide.

Description

Method for producing lithium hydroxide using lithium sulfate and barium oxide {Method for producing lithium hydroxide using lithium sulfate and barium oxide}

The present invention relates to a method for producing lithium hydroxide, and more specifically, by using a low-purity lithium sulfate solution, the process is simple and economical compared to the prior art, energy efficiency is improved, and lithium hydroxide can be produced in an environmentally friendly way because there is no waste generation. It is a method for producing lithium hydroxide using lithium sulfate and barium oxide.

In general, a secondary battery for an electric vehicle mainly considers characteristics such as stability, capacity, and output, and a cathode such as NCA (Nickel-Cobalt-Aluminum) or High-Ni NCM 811 having a nickel content of 80 mol% or more There is a tendency to use ashes.

Unlike conventional cathode materials, NCA and NCM 811 cathode materials are manufactured using lithium hydroxide instead of lithium sulfate as a lithium source. This is because when the nickel content is 80 mol% or more in the cathode material manufacturing process, the electric storage capacity characteristics can be easily implemented only when lithium hydroxide, which has relatively excellent reactivity and can be fired at a low temperature, is used.

Lithium is traditionally extracted from salt lakes and ores. When lithium is extracted from salt lakes, a process of converting water-soluble lithium chloride into lithium sulfate (water solubility: 1.29g/100mL, 20°C) with low water solubility, precipitating it as a precipitate, and then converting it into lithium hydroxide is used. .

In the case of extracting lithium from an ore, the ore is roasted with sulfuric acid and eluted in water to prepare a lithium sulfur oxide solution, and then lithium hydroxide is produced through lithium sulfate having low water solubility, similar to the process of extracting lithium from a salt lake. . Traditional lithium hydroxide production methods have a problem in that it is difficult to recover lithium below the solubility of lithium sulfate as an intermediate product (see FIG. 1).

Here, in the process of converting lithium sulfate to lithium hydroxide, lithium sulfate is dissolved in water, reacted with calcium hydroxide to remove calcium carbonate generated as a precipitate, and then the lithium hydroxide remaining in the solution is concentrated to obtain high-purity lithium hydroxide. This process can be represented by the following reaction scheme:

[reaction formula]

Li ₂ CO ₃ + Ca(OH) ₂ → 2LiOH + CaCO ₃ (s)↓

However, the reaction in the above reaction scheme proceeds as a water-based reaction, but the water solubility of the reactants, lithium sulfate and calcium hydroxide, is very low at 1.29g/100mL (25℃) and 0.173g/100mL (20℃), respectively, so they cannot be reacted at once. Since the amount of reactants present is limited and a relatively large amount of water is used, the amount of water that needs to be evaporated to separate lithium hydroxide later increases, resulting in increased energy consumption.

In addition, since calcium carbonate can be dissolved in water to some extent, the lithium hydroxide solution contains calcium carbonate to some extent, and the calcium ions derived from it can greatly reduce the performance of the lithium ion battery. Lithium hydroxide has a problem in that it is necessary to recrystallize 2 to 3 times to obtain battery-grade high-purity lithium hydroxide.

Although many studies are being conducted to solve these problems, an optimal solution has not yet been developed.

Korean Patent Publication No. 10-2016-0002578

The present inventors have completed the present invention by developing a technique for producing lithium hydroxide using a low-purity lithium sulfate solution and barium oxide as a result of numerous studies.

Accordingly, an object of the present invention is to provide a method for producing lithium hydroxide using lithium sulfate and barium oxide, which can be produced with high purity while maximizing the recovery rate of lithium by adding barium oxide and/or barium oxide-containing solid material to a low-purity lithium sulfate solution. is to do

Another object of the present invention is that the process is simple compared to the prior art, so it is very economical, energy efficiency is improved, and a continuous process can be implemented by recycling insoluble by-products, so there is no waste generation, and hydrogen sulfide generated when the starting material contains a sulfur component is removed from the atmosphere. It is possible to manufacture sulfuric acid (H ₂ SO ₄ ) by collecting it so that it does not cause environmental pollution by being discharged into the atmosphere, and by recycling the carbon dioxide generated during the process, it is possible to reduce the amount of carbon dioxide emitted into the atmosphere, which is an eco-friendly low-purity lithium sulfate solution and barium oxide To provide a method for producing lithium hydroxide using.

The object of the present invention is not limited to the above-mentioned object, and even if not explicitly mentioned, the object of the invention that can be recognized by those skilled in the art from the description of the detailed description of the invention to be described later may also be included. .

In order to achieve the above object of the present invention, the present invention provides a first leaching step of forming a first solid-liquid mixture by adding barium oxide to a low-purity lithium sulfate solution; a first filtration step of separating the first solid-liquid mixture into an aqueous lithium hydroxide solution and an insoluble by-product; and an evaporation step of evaporating the lithium hydroxide aqueous solution obtained in the first filtration step to obtain lithium hydroxide.

In a preferred embodiment, a first reduction heat treatment step of mixing the carbon source with the insoluble by-product obtained in the first filtration step and performing a first heat treatment in a reducing atmosphere to obtain a first reduction heat treatment product; a second leaching step of adding the first reduction heat treatment product to water containing carbon dioxide to form a second solid-liquid mixture containing a precipitate containing barium carbonate; A second filtration step of filtering the second solid-liquid mixture to obtain a precipitate containing barium carbonate; A second reduction heat treatment step of mixing a carbon source with the barium carbonate-containing precipitate and performing a second heat treatment in a reducing atmosphere; and recycling the barium oxide-containing solid material obtained in the second reduction heat treatment step as barium oxide used in the first leaching step.

In a preferred embodiment, a first reduction heat treatment step of mixing the carbon source with the insoluble by-product obtained in the first filtration step and performing a first heat treatment in a reducing atmosphere to obtain a first reduction heat treatment product; a third leaching step of adding water to the first reduction heat treatment product to form a third solid-liquid mixture containing an aqueous solution of barium compound and impurities; a third filtration step of filtering the third solid-liquid mixture to separate the barium compound aqueous solution and impurities; a fourth leaching step of adding the barium compound aqueous solution to water containing carbon dioxide to form a fourth solid-liquid mixture containing a precipitate containing barium carbonate; A fourth filtration step of filtering the fourth solid-liquid mixture to obtain a precipitate containing barium carbonate; A second reduction heat treatment step of mixing a carbon source with the barium carbonate-containing precipitate and performing a second heat treatment in a reducing atmosphere; and recycling the barium oxide-containing solid material obtained in the second reduction heat treatment step as barium oxide used in the first leaching step.

In a preferred embodiment, the reaction represented by Reaction Formula 1 below occurs in the first leaching step.

[Scheme 1]

Li ₂ SO ₄ (aq.) + BaO(s) + H ₂ O → 2LiOH(aq.) + BaSO ₄ (s)

In a preferred embodiment, the reaction represented by the following Reaction Formula 2 occurs in the evaporation step.

[Scheme 2]

LiOH + xH ₂ O → LiOHㅇH ₂ O

In a preferred embodiment, one or more reactions represented by Reaction Scheme 3 and Reaction Scheme 4 occur in the first reduction heat treatment step.

[Scheme 3]

BaSO ₄ (s) + 2C (s) → BaS (s) + 2CO ₂ (g)

[Scheme 4]

BaSO ₄ (s) + 4C (s) → BaS (s) + 4CO (g)

2CO + O ₂ → 2CO ₂

In a preferred embodiment, the first reduction heat treatment product includes BaS(s).

In a preferred embodiment, one or more reactions represented by Scheme 5 and Scheme 6 below occur in the second leaching step.

[Scheme 5]

BaS(s) + CO ₂ (g) + H ₂ O (l) → BaCO ₃ (s) + H ₂ S (g)

[Scheme 6]

2BaS(s) + 2H ₂ O(l) → Ba(SH) ₂ (aq.) + Ba(OH) ₂ (aq.)

In a preferred embodiment, the reaction represented by Scheme 7 below occurs in the third leaching step.

[Scheme 7]

2BaS(s) + 2H ₂ O(l) → Ba(SH) ₂ (aq.) + Ba(OH) ₂ (aq.) + Impurities(s)

In a preferred embodiment, the reaction represented by Scheme 8 below occurs in the fourth leaching step.

[Scheme 8]

Ba(SH) ₂ (aq.) + Ba(OH) ₂ (aq.) + 2CO ₂ (g) → 2BaCO ₃ (s) + 2H ₂ S(g)

In a preferred embodiment, the carbon dioxide used in the second leaching step or the fourth leaching step includes carbon dioxide generated in the first reduction heat treatment step.

In a preferred embodiment, the filtrate obtained in the second filtration step is reused in the first leaching step.

In a preferred embodiment, the filtrate contains Ba(SH) ₂ .

In a preferred embodiment, the filtrate obtained in the fourth filtration step is reused in the fourth leaching step.

In a preferred embodiment, the filtrate contains at least one of Ba(OH) ₂ and Ba(SH) ₂ .

In a preferred embodiment, the reaction represented by the following Scheme 9 occurs in the second reduction heat treatment step.

[Scheme 9]

BaCO ₃ (s) + C (s) → BaO (s) + 2CO (g)

2CO + O ₂ → 2CO ₂

In a preferred embodiment, the first reduction heat treatment step is performed at 500 °C to 1200 °C.

In a preferred embodiment, the second reduction heat treatment step is performed at 800 °C to 1200 °C.

In a preferred embodiment, the carbon source is at least one selected from the group consisting of graphite, activated carbon, carbon black, amorphous carbon, methane gas, and combinations thereof.

In a preferred embodiment, in the first reduction heat treatment step, mixing is performed such that the molar ratio of barium sulfate and carbon source contained in the insoluble by-product is 1:0.95 to 1:2.

In a preferred embodiment, in the second reduction heat treatment step, mixing is performed such that the molar ratio of barium carbonate and carbon source included in the barium carbonate-containing precipitate is 1:0.95 to 1:2.

In a preferred embodiment, lithium sulfate and BaO are included in a molar ratio of 1:0.95 to 1:2 in the first solid-liquid mixture.

In a preferred embodiment, hydrogen sulfide generated in any one or more reactions of Schemes 5 to 8 is collected and recovered as one or more compounds of sulfuric acid (H ₂ SO ₄ ), sodium sulfide (Na ₂ S), and sulfur (S). It further includes the steps of

In a preferred embodiment, in the recovering step, a reaction represented by Scheme 10 occurs to generate sulfuric acid.

[Scheme 10]

2H ₂ S(g) + 3O ₂ (g) → 2SO ₂ (g) + 2H ₂ O(g)

2SO ₂ (g) + O ₂ (g) → 2SO ₃ (g)

2SO ₃ (g) + 2H ₂ O (g) → 2H ₂ SO ₄ (g)

In a preferred embodiment, in the recovering step, a reaction represented by Scheme 11 further occurs to generate sulfur.

[Scheme 11]

H ₂ S(g) + H ₂ SO ₄ (g) → S + SO ₂ (g) + 2H ₂ O(g)

2H ₂ S(g) + SO ₂ (g) → 2H ₂ O + 3S

3H ₂ S(g) + H ₂ SO ₄ (g) → 4S + 4H ₂ O(g)

In a preferred embodiment, in the recovering step, a reaction represented by Scheme 12 occurs to generate sulfur.

[Scheme 12]

H ₂ S(g) + 2Fe ³⁺ → S + 2Fe ²⁺ +2H ⁺

2Fe ²⁺ + 0.5O ₂ + 2H ⁺ → 2Fe ³⁺ + H ₂ O

According to the above-described method for producing lithium hydroxide of the present invention, it is possible to produce high purity while minimizing the loss rate of lithium by using at least one of low-purity lithium sulfate solution, barium oxide, and barium oxide-containing solid material.

In addition, according to the lithium hydroxide manufacturing method of the present invention, the process is simple compared to the prior art, so it is very economical, improves energy efficiency, and realizes a continuous process by recycling insoluble by-products, so there is no waste generation and when the starting material contains sulfur Hydrogen sulfide generated can be produced by collecting sulfuric acid (H ₂ SO ₄ ) so as not to cause environmental pollution by being discharged into the atmosphere, and by recycling carbon dioxide generated during the process, it is eco-friendly because it can reduce carbon dioxide emitted into the atmosphere.

These technical effects of the present invention are not limited to the above-mentioned scope, and even if not explicitly mentioned, the effects of the invention that can be recognized by those skilled in the art from the description of specific contents for the practice of the invention described later included of course

1 is a schematic diagram showing a traditional lithium hydroxide manufacturing method.
Figures 2a and 2b is a schematic diagram showing a process flow showing one embodiment of the lithium hydroxide manufacturing method according to the present invention.
3 is an XRD analysis of the insoluble by-products obtained after the first filtration step in the present invention and shows a graph of the results.
Figures 4a and 4b show graphs and real photos of the result of XRD analysis of the lithium hydroxide crystals obtained after performing the evaporation step of obtaining lithium hydroxide, respectively.
5 is a thermodynamic simulation result graph for the temperature conditions of the first reduction heat treatment step.
6 is a graph showing the results of XRD analysis of heat treatment products obtained in the first reduction heat treatment step.
7 is a thermodynamic simulation result graph for the temperature conditions of the second reduction heat treatment step.
8a and 8b are graphs of XRD analysis results of heat treatment products obtained by treatment at different temperatures in the second reduction heat treatment step.

Terms used in the present invention are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, terms such as "comprise" or "having" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the description of the invention, but one or more other It should be understood that it does not preclude the possibility of addition or existence of features, numbers, steps, operations, components, parts, or combinations thereof.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. These terms are only used for the purpose of distinguishing one component from another. For example, a first element may be termed a second element, and similarly, a second element may be termed a first element, without departing from the scope of the present invention.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in the present invention, they should not be interpreted in an ideal or excessively formal meaning. don't

In interpreting the components, even if there is no separate explicit description, it is interpreted as including the error range. In particular, when the terms "about", "substantially", etc. of degree are used, they may be construed as being used in a sense at or close to that number when manufacturing and material tolerances inherent in the stated meaning are given. .

In the case of a description of a temporal relationship, for example, when a temporal precedence relationship is described as 'after', 'continue to', 'after ~', 'before', etc., 'immediately' or 'directly' Including non-consecutive cases unless ' is used.

Hereinafter, the technical configuration of the present invention will be described in detail with reference to the accompanying drawings and preferred embodiments.

However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Like reference numbers used to describe the invention throughout the specification indicate like elements.

The technical features of the present invention are that it can be produced with high purity while minimizing the loss of lithium by using a low-purity lithium sulfate solution and barium oxide and/or barium oxide-containing solid material, and is very economical and energy-saving because the process is simple compared to the prior art. Efficiency is improved and insoluble by-products can be recycled to implement a continuous process, so there is no waste generation, and sulfuric acid (H ₂ SO ₄ ) is produced by collecting hydrogen sulfide generated when the starting material contains sulfur components to prevent environmental pollution from being discharged into the atmosphere. It can be manufactured, and by recycling carbon dioxide generated during the process, carbon dioxide emitted into the atmosphere can be reduced, and thus an environmentally friendly low-purity lithium sulfate solution and a lithium hydroxide manufacturing method using barium oxide are provided.

Therefore, the lithium hydroxide manufacturing method of the present invention includes a first leaching step of forming a first solid-liquid mixture by adding barium oxide to a low-purity lithium sulfate solution; a first filtration step of separating the first solid-liquid mixture into an aqueous lithium hydroxide solution and an insoluble by-product; and an evaporation step of obtaining lithium hydroxide by evaporating the aqueous lithium hydroxide solution obtained in the first filtration step. If necessary, as shown in FIG. 2 , a solid material containing barium oxide may be prepared using insoluble by-products obtained in the first filtration step and recycled into barium oxide required in the first leaching step.

Since the first leaching step is performed by adding barium oxide or barium oxide-containing solid material to a low-purity lithium sulfate aqueous solution and then stirring, a reaction represented by Reaction Formula 1 below occurs. Therefore, the first solid-liquid mixture obtained in the first leaching step contains at least lithium hydroxide and barium sulfate.

[Scheme 1]

Li ₂ SO ₄ (aq.) + BaO(s) + H ₂ O → 2LiOH(aq.) + BaSO ₄ (s)

That is, in the first leaching step, the reaction represented by Reaction Formula 1 occurs by adding solid barium oxide and/or barium oxide-containing solid material to the low-purity lithium sulfate solution and then stirring. The ions react with barium oxide and/or barium ions of barium oxide-containing solid materials to precipitate barium sulfate, which is an insoluble compound, to obtain an aqueous solution of lithium hydroxide. At this time, the first solid-liquid mixture may include lithium sulfate and barium oxide in a molar ratio of 1: 1 to 1: 2. The molar ratio of lithium sulfate and barium oxide was determined through experiments. Since the aqueous solution included in the first solid-liquid mixture contains other impurities such as lithium sulfate, the purity of lithium hydroxide obtained by performing the evaporation step may be lowered.

When the first leaching step is performed as described above, a first solid-liquid mixture is formed, and a first filtration step may be performed to separate the aqueous lithium hydroxide solution and insoluble by-products included in the first solid-liquid mixture. The first filtration step is performed by a solid-liquid separation method. Upon solid-liquid separation, an insoluble by-product containing precipitated solid barium sulfate and an aqueous solution of lithium hydroxide as a filtrate can be obtained. As a solid-liquid separation method, most known methods such as centrifugation can be used, but since the particle size of the barium sulfate precipitate is fine and has some viscosity, solid-liquid separation by filter press may be preferable.

In order to obtain lithium hydroxide, an evaporation step of evaporating the lithium hydroxide aqueous solution obtained as a filtrate may be performed. In the evaporation step, a reaction represented by the following reaction formula 2 occurs, so that high-purity lithium hydroxide suitable for a lithium battery can be obtained. The evaporation step may be performed by treating the lithium hydroxide solution at 40 to 60° C. in a vacuum. This is because when the aqueous solution of lithium hydroxide comes into contact with air, carbon dioxide in the air is dissolved into the solution, and when the amount of carbon dioxide is excessive, lithium carbonate is generated during the evaporation process, which may adversely affect the purity of lithium hydroxide.

[Scheme 2]

LiOH + xH ₂ O → LiOHㅇH ₂ O

Before or after the evaporation step or at the same time, a continuous process is performed by preparing barium oxide-containing solid material using the insoluble by-product obtained in the first filtration step and recycling the produced barium oxide-containing solid material as barium oxide in the first leaching step. Process costs can be reduced through resource recycling, so let's take a closer look. Here, the method for producing the barium oxide-containing solid material can be divided into a first method of which an embodiment is shown in FIG. 2A and a second method of which an embodiment is shown in FIG. 2B, as will be described later. The first method is a method mainly used in the continuous process in which the method for producing lithium hydroxide of the present invention is implemented, and when the continuous process is performed for several months or more according to the first method, the impurities contained in the low-purity lithium sulfate solution used as the starting material are reduced. As a result, a problem in that the purity of the barium oxide-containing solid material produced by the first method is lowered. The second method is to solve this problem, and as shown in FIG. 2, the purity of BaS included in the first reduction heat treatment product is initially 99.5%, but as the first method is continuously performed, the content of impurities gradually increases. Therefore, the purity of the barium oxide-containing solid material can be increased by performing the second method at least once every three months to remove impurities in a continuous process.

That is, the first method for producing a barium oxide-containing solid material using the insoluble by-product obtained in the first filtration step is to mix the carbon raw material with the insoluble by-product obtained in the first filtration step and perform the first heat treatment in a reducing atmosphere for the first reduction. A first reduction heat treatment step of obtaining a heat treatment product; a second leaching step of adding the first reduction heat treatment product to water containing carbon dioxide to form a second solid-liquid mixture containing a precipitate containing barium carbonate; A second filtration step of filtering the second solid-liquid mixture to obtain a precipitate containing barium carbonate; A second reduction heat treatment step of mixing a carbon source with the barium carbonate-containing precipitate and performing a second heat treatment in a reducing atmosphere; And recycling the barium oxide-containing solid material obtained in the second reduction heat treatment step as barium oxide used in the first leaching step;

The second method includes a first reduction heat treatment step of mixing the insoluble by-product obtained in the first filtration step with a carbon source and performing a first heat treatment in a reducing atmosphere to obtain a first reduction heat treatment product; a third leaching step of adding water to the first reduction heat treatment product to form a third solid-liquid mixture containing an aqueous solution of barium compound and impurities; a third filtration step of filtering the third solid-liquid mixture to separate the barium compound aqueous solution and impurities; a fourth leaching step of adding the barium compound aqueous solution to water containing carbon dioxide to form a fourth solid-liquid mixture containing a precipitate containing barium carbonate; A fourth filtration step of filtering the fourth solid-liquid mixture to obtain a precipitate containing barium carbonate; A second reduction heat treatment step of mixing a carbon source with the barium carbonate-containing precipitate and performing a second heat treatment in a reducing atmosphere; and recycling the barium oxide-containing solid material obtained in the second reduction heat treatment step as barium oxide used in the first leaching step.

As described above, since both the first method and the second method are intended to produce a barium oxide-containing solid material using the insoluble by-product obtained in the first filtration step, the process between the first reduction heat treatment step and the second reduction heat treatment step, that is, barium carbonate It can be seen that the first reduction heat treatment step, the second reduction heat treatment step, and the step of recycling into barium oxide are commonly included, although the process of obtaining the precipitate is different. Hereinafter, the first method will be mainly described, and then the second method will be described only with different processes.

In common in the first method and the second method, the first reduction heat treatment step is performed by mixing the carbon raw material with the insoluble by-product obtained in the first filtration step and performing primary heat treatment in a reducing atmosphere. As an embodiment, an inert atmosphere (nitrogen, argon) etc.) at 500 ° C to 1200 ° C for 2 to 4 hours. The treatment conditions are experimentally determined, and as shown in FIG. 5, if the heat treatment temperature is less than 500 ° C, barium sulfate may not be completely decomposed, and if the treatment is performed at a high temperature exceeding 1200 ° C, energy costs rapidly increase, resulting in inefficiency. there may be In the first reduction heat treatment step performed as described above, reactions represented by Reaction Schemes 3 and 4 below occur, so that the solid first reduction heat treatment product obtained in the reduction heat treatment step includes BaS.

[Scheme 3]

BaSO ₄ (s) + 2C (s) → BaS (s) + 2CO ₂ (g)

[Scheme 4]

BaSO ₄ (s) + 4C (s) → BaS (s) + 4CO (g)

2CO + O ₂ → 2CO ₂

The carbon source used in the first reduction heat treatment step may be at least one selected from the group consisting of combinations thereof such as graphite, activated carbon, carbon black, and amorphous carbon, and the molar ratio of barium sulfate contained in insoluble by-products to the carbon source is 1. : 0.95 to 1:2 may be mixed, but if the carbon raw material is added at a molar ratio of less than 1:0.95, there is a concern that the conversion of barium sulfate to BaS may not be sufficiently achieved, and the molar ratio exceeds 1:2 This is because if a raw material for carbon is added, there is a risk of increasing process costs in BaS conversion and unnecessary waste of resources.

In addition, carbon dioxide generated when the reaction represented by Reaction Formula 3 and Reaction Formula 4 occurs is discharged into the atmosphere and is collected so that it is not used for the greenhouse effect, and is converted into carbon dioxide used in the second leaching step and/or the fourth leaching step described later. can be implemented to be used.

In order to obtain a precipitate containing barium carbonate from the first reduction heat treatment product, the first method includes performing a second leaching step and a second filtration step as shown in FIG. 2A, and the second method is shown in FIG. 2B. As shown, it can be seen that it includes performing the third leaching step, the third filtration step, the fourth leaching step, and the fourth filtration step.

In the first method, the second leaching step is performed by adding the solid first reduction heat treatment product obtained in the first reduction heat treatment step to carbon dioxide-containing water and then stirring it, so reactions represented by the following reaction formulas 5 and 6 occur. will do Therefore, the second solid-liquid mixture obtained in the second leaching step contains at least BaCO ₃ (s), Ba(SH) ₂ (aq.) and Ba(OH) ₂ (aq.).

[Scheme 5]

BaS(s) + CO ₂ (g) + H ₂ O (l) → BaCO ₃ (s) + H ₂ S (g)

[Scheme 6]

2BaS(s) + 2H ₂ O(l) → Ba(SH) ₂ (aq.) + Ba(OH) ₂ (aq.)

That is, in the second leaching step, since the reaction represented by Reaction Formula 5 and Reaction Formula 6 occurs by adding barium oxide, a first reduction heat treatment product mainly composed of BaS in solid state, to water containing carbon dioxide and then stirring, when the reaction occurs Carbonate ions formed by dissolving carbon dioxide in water react with barium ions of barium sulfide to precipitate as an insoluble compound, barium carbonate-containing precipitate, and an aqueous solution containing at least Ba(SH) ₂ (aq.) can be obtained. At this time, the second solid-liquid mixture may include carbonate ions and barium ions in a molar ratio of 1: 1 to 1: 2. The molar ratio of carbonate ions and barium ions was determined through experiments. Other impurities may be included in the barium carbonate-containing precipitate included in the second solid-liquid mixture, so that the purity of the barium oxide-containing solid material obtained by performing the second reduction heat treatment step may be lowered. In addition, one or more of sulfuric acid (H ₂ SO ₄ ), sodium sulfide (Na ₂ S), and sulfur (S) is collected so that the hydrogen sulfide gas generated when the reaction represented by Scheme 5 occurs is not discharged and becomes an air pollutant. It may be implemented to further include the step of recovering the compound.

In this way, when the second leaching step is performed, a second solid-liquid mixture is formed. In order to separate the barium carbonate-containing precipitate and the aqueous solution containing Ba(SH) ₂ (aq.) in the second solid-liquid mixture, a second filtration is performed. steps can be performed. The second filtration step may be performed by a solid-liquid separation method similar to the first filtration step. The filtrate obtained in the second filtration step is re-introduced into the second leaching step to precipitate the contained barium ions as barium carbonate without waste, and at the same time it can be recycled as necessary water in the second leaching step.

In the second method, the third leaching step is performed by adding water to the solid first reduction heat treatment product obtained in the first reduction heat treatment step and then stirring it. As described above, since the first reduction heat treatment product contains impurities, , a reaction represented by Scheme 7 below occurs. Therefore, the third solid-liquid mixture obtained in the third leaching step includes at least the impurity (s), Ba(SH) ₂ (aq.) and Ba(OH) ₂ (aq.).

[Scheme 7]

2BaS(s) + 2H ₂ O(l) → Ba(SH) ₂ (aq.) + Ba(OH) ₂ (aq.) + Impurities(s)

That is, in the third leaching step, the reaction represented by Reaction Formula 7 occurs by adding the first reduction heat treatment product barium oxide in a solid state containing impurities due to poor purity to water and stirring, so that Ba(OH) ₂ (aq.) And an aqueous solution of a barium compound containing Ba(SH) ₂ (aq.) can be obtained. In particular, when the reaction represented by Scheme 7 occurs, a small amount of heavy metals acting as impurities are removed from the aqueous solution of barium compounds containing Ba(OH) ₂ (aq.) and Ba(SH) ₂ (aq.) in the form of oxides or sulfides. It can be. In addition, one or more of sulfuric acid (H ₂ SO ₄ ), sodium sulfide (Na ₂ S), and sulfur (S) is collected so that the hydrogen sulfide gas generated when the reaction represented by Scheme 7 occurs is not discharged and becomes an air pollutant. It may be implemented to further include the step of recovering the compound.

When the third leaching step is performed as described above, a third solid-liquid mixture is formed, and a third filtration step may be performed to separate the barium compound aqueous solution and impurities included in the third solid-liquid mixture from each other. The third filtration step may be performed by a solid-liquid separation method similar to the first filtration step. When the third solid-liquid mixture is separated from solid-liquid by performing the third filtration step as described above, the precipitated solid impurities and the filtrate, a barium compound aqueous solution, can be obtained.

Since the fourth leaching step is performed by adding carbon dioxide to the barium compound aqueous solution obtained in the third filtration step and then stirring it, a reaction represented by Reaction Formula 8 below occurs. Accordingly, the fourth solid-liquid mixture obtained in the fourth leaching step includes at least BaCO ₃ (s) and Ba(SH) ₂ (aq.).

[Scheme 8]

Ba(SH) ₂ (aq.) + Ba(OH) ₂ (aq.) + 2CO ₂ (g) → 2BaCO ₃ (s) + 2H ₂ S(g)

That is, in the fourth leaching step, the reaction represented by Scheme 8 occurs by adding carbon dioxide to an aqueous solution of a barium compound containing Ba(SH) ₂ (aq.) and Ba(OH) ₂ (aq.) and then stirring it. When the reaction occurs, the carbonate ion formed by dissolving carbon dioxide in water reacts with the barium ion of the barium compound to precipitate as an insoluble compound, barium carbonate-containing precipitate, and an aqueous solution containing at least Ba(SH) ₂ (aq.) can be obtained. there will be At this time, the fourth solid-liquid mixture may include carbonate ions and barium ions in a molar ratio of 1: 1 to 1: 2. The molar ratio of carbonate ions and barium ions was determined through experiments. Other impurities may be included in the barium carbonate-containing precipitate included in the fourth solid-liquid mixture, so that the purity of the barium oxide-containing solid material obtained by performing the second reduction heat treatment step may be lowered. In addition, one or more of sulfuric acid (H ₂ SO ₄ ), sodium sulfide (Na ₂ S), and sulfur (S) is collected so that the hydrogen sulfide gas generated when the reaction represented by Scheme 8 occurs is not emitted and becomes an air pollutant. It may be implemented to further include the step of recovering the compound.

As such, when the fourth leaching step is performed, a fourth solid-liquid mixture is formed. In order to separate the barium carbonate-containing precipitate and the aqueous solution containing Ba(SH) ₂ (aq.) in the fourth solid-liquid mixture, the fourth filtration is performed. steps can be performed. The fourth filtration step may be performed by the solid-liquid separation method in the same way as the first filtration step. The filtrate obtained in the fourth filtration step is reintroduced to the fourth leaching step to precipitate barium ions as a precipitate containing barium carbonate without waste. At the same time, it can be recycled as water needed in the fourth leaching step.

In order to obtain a barium oxide-containing solid material from the barium carbonate-containing precipitate obtained in the second filtration step of the first method and/or the fourth filtration step of the second method, the second reduction heat treatment step is performed in an inert atmosphere (nitrogen, argon, etc.) It can be carried out by treatment at 800 ° C to 1200 ° C for 2 to 4 hours. As shown in FIG. 7, if the heat treatment temperature is less than 800 ° C, barium carbonate may not be completely decomposed, and at a high temperature exceeding 1200 ° C If this is done, there may be inefficiencies due to the rapid increase in energy costs. Since the reaction represented by Reaction Formula 9 below occurs in the second reduction heat treatment step performed as described above, the solid phase heat treatment product obtained in the second reduction heat treatment step includes BaO.

[Scheme 9]

BaCO ₃ (s) + C (s) → BaO (s) + 2CO (g)

2CO + O ₂ → 2CO ₂

The carbon source used in the second reduction heat treatment step may be at least one selected from the group consisting of combinations thereof, such as graphite, activated carbon, carbon black, and amorphous carbon, and the molar ratio of barium carbonate contained in the barium carbonate-containing precipitate: carbon source Mixing may be performed so that is 1:0.95 to 1:2, but if the carbon raw material is added at a molar ratio of less than 1:0.95, there is a concern that the conversion of barium carbonate to BaO may not be sufficiently achieved, and the molar ratio is 1: This is because if the carbon raw material is added in excess of 2, process costs may increase in BaO conversion, and unnecessary resource waste may occur.

If necessary, the carbon dioxide generated when the reaction represented by Scheme 9 occurs is discharged into the atmosphere and is collected so that it is not used to represent the greenhouse effect, so that it can be used as carbon dioxide used in the second leaching step and / or the fourth leaching step. can

On the other hand, as described above, the hydrogen sulfide treatment step is one of sulfuric acid (H ₂ SO ₄ ), sodium sulfide (Na ₂ S), and sulfur (S) by collecting hydrogen sulfide generated in any one or more reactions of Reaction Formulas 5 to 8. In the step of recovering the above compound, a useful sulfur compound can be prepared by lowering the concentration of hydrogen sulfide discharged to the atmosphere and simultaneously generating one or more of the reactions represented by Schemes 10 to 12 below.

[Scheme 10]

2H ₂ S(g) + 3O ₂ (g) → 2SO ₂ (g) + 2H ₂ O(g)

2SO ₂ (g) + O ₂ (g) → 2SO ₃ (g)

2SO ₃ (g) + 2H ₂ O (g) → 2H ₂ SO ₄ (g)

That is, sulfuric acid can be produced from hydrogen sulfide gas through Reaction Formula 10, and sulfur dioxide gas (SO ₂ (g)) is converted into sulfur _dioxide (SO _{2 3} (g)) Concentrated sulfuric acid can be produced by oxidizing and condensing the oxidized sulfur dioxide in a wet treatment process.

When sulfuric acid is generated in this way, sulfur can be produced using the generated sulfuric acid using the Claus process as shown in Scheme 11.

[Scheme 11]

H ₂ S(g) + H ₂ SO ₄ (g) → S + SO ₂ (g) + 2H ₂ O(g)

2H ₂ S(g) + SO ₂ (g) → 2H ₂ O + 3S

3H ₂ S(g) + H ₂ SO ₄ (g) → 4S + 4H ₂ O(g)

In addition, when hydrogen sulfide is generated in this way, sulfur can be generated using the process shown in Scheme 12.

[Scheme 12]

H ₂ S(g) + 2Fe ³⁺ (g) → S + 2Fe ²⁺ +2H ⁺

2Fe ²⁺ + 0.5O ₂ + 2H ⁺ → Fe ³⁺ + H ₂ O

Through the above configuration, as shown in FIGS. 2A and 2B, the lithium hydroxide manufacturing method of the present invention can not only produce high-purity lithium hydroxide, but also oxidize it using BaS, the first reduction heat treatment product obtained as a by-product in the process. By implementing a continuous process to manufacture barium-containing solid materials and recycle the produced barium oxide-containing solid materials as barium oxide in the first leaching step, lithium hydroxide can be produced in high purity, while reducing the processing cost of by-products, as well as being environmentally friendly, It can be seen that the cost of raw materials can also be reduced.

Example 1

Lithium hydroxide was prepared by performing the following steps as shown in FIG. 2a.

1. First leaching step

A first solid-liquid mixture was obtained by adding 1 liter of a low-purity lithium sulfate aqueous solution in which about 110 g (1 molar equivalent) of lithium sulfate per liter was dissolved in a reaction vessel equipped with an agitator, adding 153 g of barium oxide, and stirring at room temperature for 1 hour. prepared.

2. First filtration step

The first solid-liquid mixture was filtered through a vacuum filter to separate a lithium hydroxide solution and an insoluble by-product.

3. Evaporation step

The lithium hydroxide solution obtained in the first filtration step was treated under vacuum at 50° C. to remove water and obtain lithium hydroxide crystals.

4. First reduction heat treatment step

The insoluble by-product (BaSO ₄ ) and carbon black separated in the first filtration step were charged into an electric furnace so that the molar ratio of barium sulfate: carbon source contained in the insoluble by-product was 1: 1, and the mixture was heated at 900 ° C in a nitrogen atmosphere. Reduction heat treatment was performed for a period of time.

5. Second leaching step

A second solid-liquid mixture was prepared by adding 100 g of the solid first reduction heat treatment product obtained in the first reduction heat treatment step to 1 liter of water in which carbon dioxide was dissolved in a reaction vessel equipped with an agitator and stirring at room temperature for 1 hour.

6. Second filtration step

The second solid-liquid mixture was filtered through a vacuum filter to separate a precipitate containing barium carbonate and a filtrate.

7. Second reduction heat treatment step

The barium carbonate-containing precipitate (BaCO ₃ ) separated in the second filtration step and carbon black as a carbon raw material were charged into an electric furnace so that the molar ratio of barium carbonate contained in insoluble by-products: carbon raw material was 1: 1, and heated at 800 ° C in a nitrogen atmosphere. Reduction heat treatment was performed for 3 hours to obtain a barium oxide-containing solid material.

8. Step of recycling as barium oxide in the first leaching step

The solid material containing barium oxide obtained in the second reduction heat treatment step was reused as barium oxide required for preparing the first solid-liquid mixture in the first leaching step.

Example 2

Lithium hydroxide was prepared by performing the following steps as shown in FIG. 2b, which may be performed at least once every 3 months in a continuous process for preparing lithium hydroxide.

1. First leaching step

A first solid-liquid mixture was obtained by adding 1 liter of a low-purity lithium sulfate aqueous solution in which about 110 g (1 molar equivalent) of lithium sulfate per liter was dissolved in a reaction vessel equipped with an agitator, adding 153 g of barium oxide, and stirring at room temperature for 1 hour. prepared.

2. First filtration step

The first solid-liquid mixture was filtered through a vacuum filter to separate a lithium hydroxide solution and an insoluble by-product.

3. Evaporation step

The lithium hydroxide solution obtained in the first filtration step was treated under vacuum at 50° C. to remove water and obtain lithium hydroxide crystals.

4. First reduction heat treatment step

The insoluble by-product (BaSO ₄ ) and carbon black separated in the first filtration step were charged into an electric furnace so that the molar ratio of barium sulfate: carbon source contained in the insoluble by-product was 1: 1, and the mixture was heated at 900 ° C in a nitrogen atmosphere. Reduction heat treatment was performed for a period of time.

5. Third leaching step

A third solid-liquid mixture was prepared by washing with water of 200 parts by weight per 100 parts by weight of the first reduction heat-treated product obtained in the first reduction heat treatment step.

6. Third filtration step

The third solid-liquid mixture was filtered through a vacuum filter to separate a barium compound solution and impurities.

7. 4th leaching step

A fourth solid-liquid mixture was prepared by adding carbon dioxide gas to the barium compound solution obtained in the third filtration step in a reaction vessel equipped with an agitator and stirring at room temperature for 1 hour.

8. Fourth filtration step

The fourth solid-liquid mixture was filtered through a vacuum filter to separate a precipitate containing barium carbonate and a filtrate.

9. Second reduction heat treatment step

The barium carbonate-containing precipitate (BaCO ₃ ) separated in the fourth filtration step and carbon black as a carbon raw material were charged into an electric furnace so that the molar ratio of barium carbonate contained in insoluble by-products: carbon raw material was 1: 1, and heated at 800 ° C in a nitrogen atmosphere. Reduction heat treatment was performed for 3 hours to obtain a barium oxide-containing solid material.

10. Step of recycling as barium oxide in the first leaching step

The solid material containing barium oxide obtained in the second reduction heat treatment step was reused as barium oxide required for preparing the first solid-liquid mixture in the first leaching step.

Experimental Example 1

In Example 1 and Example 2, the insoluble by-products obtained after the filtration step were analyzed by XRD, and the resulting graph is shown in FIG. 3.

From Figure 3, which is a result of analyzing the XRD results of the residues, that is, insoluble by-products, which came out as solids in Examples 1 and 2, it was confirmed that more than 99.5% of the residues in the solid phase were BaSO ₄ .

Experimental Example 2

After performing the evaporation step of obtaining lithium hydroxide in Examples 1 and 2, the obtained lithium hydroxide crystals were analyzed by XRD, and the resulting graphs are shown in FIGS. 4a and 4b.

When the evaporation step is performed on the solution containing lithium hydroxide obtained in the first filtration step, a solid product can be produced as shown in FIG. 4b. As a result of XRD, most of it is LiOH H ₂ O, and it can be confirmed that a small amount of LiOH was produced. As a result of producing lithium hydroxide using the low-purity industrial lithium sulfate solution as described above, the recovery rate of Li was 99% or more.

Experimental Example 3

Based on the thermodynamic simulation results, the conditions of the first reduction heat treatment step performed in Examples 1 and 2 were analyzed, and the first reduction heat treatment conditions obtained from the analyzed results were performed, and the resulting data are shown in FIG. 5 .

5, when BaSO ₄ , an insoluble by-product, is subjected to reduction heat treatment using carbon raw material (C), reactions represented by Reaction Formula 3 and Reaction Formula 4 occur, so that barium sulfide (BaS) can be generated, including the generated BaS. As described above, the first reduction heat treatment product is manufactured as a barium oxide-containing solid material through the first method and the second method and can be recycled. In this way, if the insoluble by-products obtained in the first filtration step can be reused as barium oxide through the first and second methods, it is expected that the economic efficiency will be greatly improved through the reduction of raw materials. In addition, it can be seen from the above results that 2CO ₂ (g) can be generated and discharged when the ratio of C in the carbon raw material is 2: 1 with respect to BaSO ₄ .

Experimental Example 4

The first heat treatment products obtained through the first reduction heat treatment in Examples 1 and 2 were analyzed by XRD, and the result graph is shown in FIG. 6 .

As shown in Figure 6, the product of the solid phase is BaS It can be confirmed that

Experimental Example 5

Based on the thermodynamic simulation results, the conditions for the second reduction heat treatment step performed in Examples 1 and 2 were analyzed, and the second reduction heat treatment conditions obtained from the analyzed results were performed, and the resulting data are shown in FIG. 7 .

From FIG. 7, when the barium carbonate-containing precipitate (BaCO ₃ ) is subjected to reduction heat treatment using the carbon raw material (C), the reaction represented by Reaction Formula 10 occurs, so that barium oxide (BaO) can be generated, and the resulting barium oxide-containing The solid material can be recycled as barium oxide in the first leaching step as described above. In addition, from the above results, it can be seen that when the ratio of C in the carbon raw material is 1: 1 with respect to BaCO ₃ , 2CO (g) can be generated and discharged, and CO (g) is oxidized to CO ₂ (g) can be emitted with If necessary, carbon dioxide may be collected and used as carbon dioxide used in the second leaching step and/or the fourth leaching step.

Experimental Example 6

As in Example 1 and Example 2, the second reduction heat treatment product obtained by performing the second reduction heat treatment temperature at 900 ° C and 1000 ° C, respectively, instead of 800 ° C, was analyzed by XRD, and the resultant graphs are shown in FIGS. 8a and 8b.

As shown in FIGS. 8a and 8b, the solid second reduction heat treatment product is BaO It can be confirmed that

Although the present invention has been shown and described with preferred embodiments as described above, it is not limited to the above embodiments, and to those skilled in the art within the scope of not departing from the spirit of the present invention Various changes and modifications will be possible.

Claims (26)

A first leaching step of forming a first solid-liquid mixture by adding barium oxide to a low-purity lithium sulfate solution;
a first filtration step of separating the first solid-liquid mixture into an aqueous lithium hydroxide solution and an insoluble by-product; and
An evaporation step of evaporating the lithium hydroxide aqueous solution obtained in the first filtration step to obtain lithium hydroxide; Lithium hydroxide manufacturing method comprising a.
According to claim 1,
a first reduction heat treatment step of mixing a carbon source with the insoluble by-product obtained in the first filtration step and performing a first heat treatment in a reducing atmosphere to obtain a first reduction heat treatment product;
a second leaching step of adding the first reduction heat treatment product to water containing carbon dioxide to form a second solid-liquid mixture containing a precipitate containing barium carbonate;
A second filtration step of filtering the second solid-liquid mixture to obtain a precipitate containing barium carbonate;
A second reduction heat treatment step of mixing a carbon source with the barium carbonate-containing precipitate and performing a second heat treatment in a reducing atmosphere; and
and recycling the barium oxide-containing solid material obtained in the second reduction heat treatment step as barium oxide used in the first leaching step.
According to claim 1,
a first reduction heat treatment step of mixing a carbon source with the insoluble by-product obtained in the first filtration step and performing a first heat treatment in a reducing atmosphere to obtain a first reduction heat treatment product;
a third leaching step of adding water to the first reduction heat treatment product to form a third solid-liquid mixture containing an aqueous solution of barium compound and impurities;
a third filtration step of filtering the third solid-liquid mixture to separate the barium compound aqueous solution and impurities;
a fourth leaching step of adding the barium compound aqueous solution to water containing carbon dioxide to form a fourth solid-liquid mixture containing a precipitate containing barium carbonate;
A fourth filtration step of filtering the fourth solid-liquid mixture to obtain a precipitate containing barium carbonate;
A second reduction heat treatment step of mixing a carbon source with the barium carbonate-containing precipitate and performing a second heat treatment in a reducing atmosphere; and
and recycling the barium oxide-containing solid material obtained in the second reduction heat treatment step as barium oxide used in the first leaching step.
According to any one of claims 1 to 3,
A method for producing lithium hydroxide, characterized in that the reaction represented by the following Reaction Formula 1 occurs in the first leaching step.
[Scheme 1]
Li ₂ SO ₄ (aq.) + BaO(s) + H ₂ O → 2LiOH(aq.) + BaSO ₄ (s)
According to any one of claims 1 to 3,
A method for producing lithium hydroxide, characterized in that the reaction represented by the following Reaction Formula 2 occurs in the evaporation step.
[Scheme 2]
LiOH + xH ₂ O → LiOHㅇH ₂ O
According to claim 2 or 3,
A method for producing lithium hydroxide, characterized in that one or more reactions represented by the following Reaction Formula 3 and Reaction Formula 4 occur in the first reduction heat treatment step.
[Scheme 3]
BaSO ₄ (s) + 2C (s) → BaS (s) + 2CO ₂ (g)
[Scheme 4]
BaSO ₄ (s) + 4C (s) → BaS (s) + 4CO (g)
2CO + O ₂ → 2CO ₂
According to claim 2 or 3,
The method of producing lithium hydroxide, characterized in that the first reduction heat treatment product includes BaS (s).
According to claim 2,
In the second leaching step, one or more reactions represented by Reaction Formula 5 and Reaction Formula 6 occur.
[Scheme 5]
BaS(s) + CO ₂ (g) + H ₂ O (l) → BaCO ₃ (s) + H ₂ S (g)
[Scheme 6]
2BaS(s) + 2H ₂ O(l) → Ba(SH) ₂ (aq.) + Ba(OH) ₂ (aq.)
According to claim 3,
A method for producing lithium hydroxide, characterized in that the reaction represented by the following Reaction Formula 7 occurs in the third leaching step.
[Scheme 7]
2BaS(s) + 2H ₂ O(l) → Ba(SH) ₂ (aq.) + Ba(OH) ₂ (aq.) + Impurities(s)
According to claim 3,
A method for producing lithium hydroxide, characterized in that the reaction represented by the following Reaction Formula 8 occurs in the fourth leaching step.
[Scheme 8]
Ba(SH) ₂ (aq.) + Ba(OH) ₂ (aq.) + 2CO ₂ (g) → 2BaCO ₃ (s) + 2H ₂ S(g)
According to claim 2 or 3,
Carbon dioxide used in the second leaching step or the fourth leaching step includes carbon dioxide generated in the first reduction heat treatment step.
According to claim 2,
The method for producing lithium hydroxide, characterized in that the filtrate obtained in the second filtration step is reused in the first leaching step.
According to claim 12,
The filtrate is a method for producing lithium hydroxide, characterized in that it contains Ba (SH) ₂ .
According to claim 3,
The method for producing lithium hydroxide, characterized in that the filtrate obtained in the fourth filtration step is reused in the fourth leaching step.
15. The method of claim 14,
The filtrate is a method for producing lithium hydroxide, characterized in that it contains at least one of Ba (OH) ₂ and Ba (SH) ₂ .
According to claim 2 or 3,
A method for producing lithium hydroxide, characterized in that the reaction represented by the following Reaction Formula 9 occurs in the second reduction heat treatment step.
[Scheme 9]
BaCO ₃ (s) + C (s) → BaO (s) + 2CO (g)
2CO + O ₂ → 2CO ₂
According to claim 2 or 3,
The first reduction heat treatment step is a lithium hydroxide manufacturing method, characterized in that carried out at 500 ℃ to 1200 ℃.
According to claim 2 or 3,
The second reduction heat treatment step is a method for producing lithium hydroxide, characterized in that carried out at 800 ℃ to 1200 ℃.
According to claim 2 or 3,
The carbon raw material is a method for producing lithium hydroxide, characterized in that at least one selected from the group consisting of graphite, activated carbon, carbon black, amorphous carbon, methane gas, and combinations thereof.
According to claim 2 or 3,
In the first reduction heat treatment step, mixing is performed such that the molar ratio of barium sulfate and carbon source contained in the insoluble by-product is 1: 0.95 to 1: 2.
According to claim 2 or 3,
In the second reduction heat treatment step, mixing is performed such that the molar ratio of barium carbonate:carbon raw material contained in the barium carbonate-containing precipitate is 1:0.95 to 1:2.
According to claim 1,
In the first solid-liquid mixture, lithium sulfate and BaO are contained in a molar ratio of 1: 0.95 to 1: 2.
According to any one of claims 8 to 10,
Capturing the hydrogen sulfide generated in any one or more reactions of Schemes 5 to 8 and recovering it as one or more compounds of sulfuric acid (H ₂ SO ₄ ), sodium sulfide (Na ₂ S), and sulfur (S) Further comprising Method for producing lithium hydroxide, characterized in that.
24. The method of claim 23,
In the recovering step, a reaction represented by Scheme 10 occurs to produce sulfuric acid.
[Scheme 10]
2H ₂ S(g) + 3O ₂ (g) → 2SO ₂ (g) + 2H ₂ O(g)
2SO ₂ (g) + O ₂ (g) → 2SO ₃ (g)
2SO ₃ (g) + 2H ₂ O (g) → 2H ₂ SO ₄ (g)
25. The method of claim 24,
In the recovering step, a reaction represented by Scheme 11 further occurs to generate sulfur.
[Scheme 11]
H ₂ S(g) + H ₂ SO ₄ (g) → S + SO ₂ (g) + 2H ₂ O(g)
2H ₂ S(g) + SO ₂ (g) → 2H ₂ O + 3S
3H ₂ S(g) + H ₂ SO ₄ (g) → 4S + 4H ₂ O(g)
24. The method of claim 23,
A method for producing lithium hydroxide, characterized in that in the recovering step, a reaction represented by Scheme 12 occurs to generate sulfur.
[Scheme 12]
H ₂ S(g) + 2Fe ³⁺ → S + 2Fe ²⁺ +2H ⁺
2Fe ²⁺ + 0.5O ₂ + 2H ⁺ → 2Fe ³⁺ + H ₂ O