CN113371738A - Preparation method for preparing lithium carbonate and co-producing magnesium hydroxide nanosheet by using feed liquid containing lithium and magnesium - Google Patents

Abstract

The invention discloses a preparation method for preparing lithium carbonate and co-producing magnesium hydroxide nanosheets from lithium and magnesium-containing feed liquid, which comprises the following steps: 1, adjusting the pH value of a lithium-containing and magnesium-containing stock solution, and reacting for 0.5-24 hours at a reaction temperature to obtain magnesium precipitate slurry; 2, carrying out solid-liquid separation on the magnesium precipitation slurry obtained after the step 1 is finished, washing and drying a solid part to obtain a magnesium hydroxide nanosheet, and obtaining a lithium-containing feed liquid with magnesium removed from a liquid part; 3, adding carbonate into the lithium-containing feed liquid without magnesium obtained in the step 2, and reacting for 0.1-12 hours to obtain lithium precipitate slurry; and 4, carrying out solid-liquid separation, washing and drying on the lithium precipitation slurry obtained in the step 3 to obtain a lithium carbonate product. The method realizes the refining magnesium removal in the lithium-containing feed liquid and the preparation of the high-valued magnesium hydroxide nanosheet in one step, and the obtained magnesium hydroxide nanosheet is regular in shape, less in lithium entrainment, free from reprocessing and capable of being directly used in practical applications such as flame retardance and the like.

Description

Preparation method for preparing lithium carbonate and co-producing magnesium hydroxide nanosheet by using feed liquid containing lithium and magnesium

Technical Field

The invention belongs to the technical field of inorganic chemistry, and particularly relates to a preparation method for preparing lithium carbonate and co-producing magnesium hydroxide nanosheets from feed liquid containing lithium and magnesium.

Background

The Qinghai is rich in salt lake resources, wherein the salt lake resources are rich in magnesium, lithium, potassium, sodium and other resources. Wherein, the physical and chemical properties of the magnesium and the lithium are similar, and the separation difficulty is large. The current method for extracting lithium from salt lake mainly comprises the following steps: (1) precipitation, (2) adsorption, (3) calcination, (4) membrane separation, and (5) extraction. The method such as adsorption method, calcination method, membrane separation method and the like has the advantage of well reducing the magnesium-lithium ratio, and is particularly suitable for extracting lithium from salt lakes such as Qinghai, Tibet, Vivian and the like. However, in the purification solution in which the magnesium-lithium ratio is reduced by these methods, a part of magnesium still exists, and the existence of this part of magnesium affects the quality of lithium salts such as lithium carbonate, lithium hydroxide, and lithium chloride, and therefore, it is necessary to purify magnesium in the lithium-containing purification solution.

The traditional method for refining and removing impurities from lithium-containing feed liquid comprises an ion exchange method and a chemical precipitation method. The ion exchange method is to make the feed liquid pass through an ion exchange column capable of removing magnesium to remove the magnesium in the feed liquid, and is suitable for the feed liquid with extremely low magnesium content. The precipitation method is a widely used method, and generally, an alkali solution is added into a lithium-containing feed liquid at a certain temperature, magnesium ions are converted into magnesium hydroxide, and the magnesium hydroxide is precipitated, filtered and removed. Magnesium hydroxide nanosheets have led extensive research by scholars because they exhibit more excellent effects in flame retardancy.

The prior art for preparing magnesium hydroxide or magnesium hydroxide nanosheets mainly has the following defects:

1. a multi-step operation such as a hydrothermal modification method, a seed crystal method, a conversion method, etc. is required.

2. A morphology directing agent such as an organic base, a seed, or a surfactant is required in the direct precipitation method (as described in patent document CN 106673027A). Not only increases the cost of raw materials, but also causes impure products.

3. The existing method for removing magnesium mainly comprises an adsorption method and a precipitation method, and magnesium hydroxide obtained by the precipitation method usually has high impurity content and irregular shape, so that the magnesium hydroxide is abandoned by enterprises. Or further modification and impurity removal are needed for utilization. The by-product contains a large amount of lithium, magnesium and other resources, and is wasted when being abandoned. Further modification or removal of impurities increases the process and production costs.

Disclosure of Invention

The invention provides a preparation method for preparing lithium carbonate and co-producing magnesium hydroxide nanosheets from lithium and magnesium-containing feed liquid, the method realizes refining magnesium removal in the lithium-containing feed liquid and preparation of high-valued magnesium hydroxide nanosheets in one step, and the obtained magnesium hydroxide nanosheets are regular in shape, less in lithium entrainment, free of reprocessing, and capable of being directly used in practical applications such as flame retardance and the like.

A preparation method for preparing lithium carbonate and co-producing magnesium hydroxide nanosheets from feed liquid containing lithium and magnesium comprises the following steps:

step 1, adjusting the pH value of a lithium-containing and magnesium-containing stock solution to 7.2-13.5, and reacting at the reaction temperature of 40-180 ℃ for 0.5-24 h to obtain magnesium precipitate slurry;

step 2, carrying out solid-liquid separation on the magnesium precipitation slurry obtained after the step 1 is finished, washing and drying a solid part to obtain a magnesium hydroxide nanosheet, and obtaining a lithium-containing feed liquid with magnesium removed from a liquid part;

step 3, adding carbonate into the lithium-containing feed liquid without magnesium obtained in the step 2, wherein the molar weight of the carbonate is 0.55-2.0 times of that of lithium in the lithium-containing feed liquid without magnesium, and reacting for 0.1-12 hours at 50-150 ℃ to obtain lithium precipitate slurry, wherein the carbonate is at least one of sodium carbonate, potassium carbonate, ammonium bicarbonate, sodium bicarbonate and potassium bicarbonate;

step 4, carrying out solid-liquid separation, washing and drying on the lithium precipitation slurry obtained in the step 3 to obtain a lithium carbonate product; the solid-liquid separation, washing and drying processes are all carried out at 50-150 ℃;

the content of magnesium ions in the feed liquid containing lithium and magnesium is 0.01-200 g/L, and the content of lithium ions is 0.01-50 g/L.

In the technical scheme, the process of adjusting the pH value of the lithium and magnesium-containing material liquid to 7.2-13.5 is realized by adding an alkali solution into the pre-precipitation material liquid, wherein the alkali solution is one or more of a NaOH solution, a KOH solution, a LiOH solution, an ammonia water solution, a hydrazine hydrate solution, an ammonium bicarbonate solution, a sodium bicarbonate solution, an ammonium bicarbonate solution, a hexamethylenetetramine solution or a urea solution.

In the technical scheme, the concentration of the alkali solution is 0.1-8 mol/L.

In the technical scheme, the content of magnesium in the lithium and magnesium-containing feed liquid is 0.1-60 g/L, and the content of lithium is 0.1-40 g/L.

In the technical scheme, the magnesium hydroxide nanosheet is 10-500 nm in particle size, 5-50 nm in thickness, and is of a sheet structure, and further is of a hexagonal sheet structure.

In the technical scheme, the reaction temperature in the step 1 is 80-150 ℃.

A method for refining a feed liquid containing lithium and magnesium, removing magnesium and producing magnesium hydroxide nanosheets in parallel comprises the following steps:

step 1, adding a co-additive into a feed liquid containing lithium and magnesium, uniformly dispersing to obtain a pretreated feed liquid, adjusting the pH of the pretreated feed liquid to 7.2-13.5, and reacting at a reaction temperature of 90-130 ℃ for 0.5-24 h to obtain magnesium precipitate slurry;

the assistant is inorganic salt, the cation in the inorganic salt is at least one cation in Li, K, Na, Ca, Zn, Ni, Co or Cu, and the anion in the inorganic salt is at least one of chloride, bromide, nitrate, sulfate, borate or carbonate;

the molar ratio of the sum of the molar weight of the co-assistant cations to the magnesium ions in the pretreated feed liquid is (0.1-10): 1;

step 2, carrying out solid-liquid separation on the magnesium precipitation slurry obtained after the step 1 is finished, washing and drying a solid part to obtain a magnesium hydroxide nanosheet, and obtaining a lithium-containing feed liquid with magnesium removed from a liquid part;

step 3, adding carbonate into the lithium-containing feed liquid with magnesium removed obtained in the step 3, wherein the molar weight of the carbonate is 0.55-2.0 times of that of lithium in the lithium-containing feed liquid with magnesium removed, and reacting for 0.1-12 hours at 50-150 ℃ to obtain lithium precipitate slurry, wherein the carbonate is at least one of sodium carbonate, potassium carbonate, ammonium bicarbonate, sodium bicarbonate, potassium bicarbonate or urea;

step 4, carrying out solid-liquid separation, washing and drying on the lithium precipitation slurry obtained in the step 3 to obtain a lithium carbonate product; the solid-liquid separation, washing and drying processes are all carried out at 50-150 ℃;

the content of magnesium ions in the feed liquid containing lithium and magnesium is 0.5-30 g/L, the content of lithium ions is 0.5-30 g/L, and the sum of the molar weight of cations of the auxiliary agent is higher than 0.5 time of the molar weight of magnesium ions;

the process of adjusting the pH value of the lithium and magnesium-containing feed liquid to 7.2-13.5 is realized by adding an alkali solution into the lithium and magnesium-containing feed liquid, wherein the alkali solution is one or more of a NaOH solution, a KOH solution, a LiOH solution, an ammonia water solution, a hydrazine hydrate solution, an ammonium bicarbonate solution, a sodium bicarbonate solution, an ammonium bicarbonate solution, a hexamethylenetetramine solution or a urea solution, and the concentration of the alkali solution is 0.5-5 mol/L.

The invention has the advantages and beneficial effects that:

the method realizes the refining magnesium removal in the lithium and magnesium-containing feed liquid and the preparation of high-value magnesium hydroxide nanosheets in one step, and the obtained magnesium hydroxide nanosheets have regular shapes, less lithium entrainment and no need of reprocessing, and can be directly used in practical applications such as flame retardance and the like. The prepared lithium carbonate has high purity.

Drawings

FIG. 1 is a scanning electron micrograph of a magnesium hydroxide product obtained in example 1;

FIG. 2 is a scanning electron micrograph of the magnesium hydroxide product obtained in example 2.

For a person skilled in the art, other relevant figures can be obtained from the above figures without inventive effort.

Detailed Description

In order to make the technical solution of the present invention better understood, the technical solution of the present invention is further described below with reference to specific examples.

Example one

A method for refining a feed liquid containing lithium and magnesium, removing magnesium and producing magnesium hydroxide nanosheets in parallel comprises the following steps:

7L of feed liquid containing lithium and magnesium, wherein Mg is contained in the feed liquid containing lithium and magnesium²⁺Content 1g/L, Li⁺The content is 15 g/L; sodium hydroxide with a concentration of 1mol/L was added dropwise to the feed solution at a rate of 2ml/s with a stirring speed of 500rpm until pH 10 gave a slurry, which was then subjected to reaction crystallization at 120 ℃ for 12 hours. Then carrying out solid-liquid separation, washing and drying the solid part to obtain a magnesium hydroxide nanosheet, obtaining a magnesium-removed lithium-containing feed liquid from the liquid part, wherein the content of lithium in the separated magnesium-removed lithium-containing feed liquid is 13g/L, and the content of magnesium is 0.05 g/L; adding 1200g of sodium carbonate into the lithium-containing feed liquid with magnesium removed at 80 ℃ for reaction for 2 hours, then carrying out hot filtration at 80 ℃, and filtering to obtain solidWashing the lithium carbonate body by deionized water at the temperature of 80 ℃, and drying to obtain a lithium carbonate product. FIG. 1 is a scanning electron micrograph of the magnesium hydroxide obtained in example 1, wherein it can be seen that the magnesium hydroxide has a regular hexagonal plate-like structure with a diameter of 40nm to 130 nm. The content of magnesium ions in the lithium carbonate product after separation and washing is lower than 0.5 ppm.

Example two

1000ml of lithium-containing feed liquid is prepared, wherein Mg²⁺Content of 100g/L, Ca²⁺Content 0.1g/L, Li⁺With a content of 5g/L (molar ratio of lithium to magnesium of 0.17), KNO was added thereto at a stirring speed of 250rpm₃The concentration was adjusted to 20g/L, and sodium hydroxide was added dropwise to the feed solution at a concentration of 2.5mol/L until the pH was 11, followed by reaction at 90 ℃ for 24 hours. And then carrying out solid-liquid separation, washing and drying the solid part to obtain a magnesium hydroxide nanosheet, obtaining a magnesium-removed lithium-containing feed liquid from the liquid part, adding sodium carbonate with the molar mass being 2 times of that of lithium ions in the lithium-containing feed liquid at 80 ℃ into the separated magnesium-removed lithium-containing feed liquid for reacting for 2 hours, carrying out heat filtration at 80 ℃, washing the filtered solid by hot water at 80 ℃, and drying to obtain a lithium carbonate product, wherein the lithium content in the separated magnesium-removed lithium-containing feed liquid is 4.95g/L, and the magnesium content in the separated magnesium-removed lithium-containing feed liquid is 0.1 g/L. FIG. 2 is a scanning electron micrograph of a magnesium hydroxide product obtained in example two, wherein the magnesium hydroxide has a hexagonal plate-like structure with a particle size of 40-80 nm. The content of magnesium ions in the obtained lithium carbonate product is lower than 1ppm, and the concentration of calcium ions is lower than 20 ppm.

EXAMPLE III

200ml of lithium-containing feed liquid is prepared, wherein Mg²⁺Content 1g/L, Li⁺The content was 15g/L (molar ratio of lithium and magnesium 51.67), LiCl was added to give a concentration of 0.2g/L, and aqueous ammonia having a concentration of 0.5mol/L was added dropwise to the feed at a rate of 1ml/s at 400rpm until the pH became 7.2 to give a slurry, which was then crystallized at 100 ℃ for 16 hours. Then carrying out solid-liquid separation, washing and drying the solid part to obtain magnesium hydroxide nanosheets, obtaining a magnesium-removed lithium-containing feed liquid from the liquid part, wherein the content of lithium in the separated magnesium-removed lithium-containing feed liquid is 15.18g/l, the content of magnesium is 0.05g/l, and the content of lithium in the magnesium-removed lithium-containing feed liquid is 80 g/lAdding potassium carbonate with the molar mass 0.55 time of lithium ions in the lithium-containing feed liquid into the mixture to react for 2 hours, then carrying out hot filtration at the temperature of 80 ℃, washing the solid obtained by filtration by hot deionized water at the temperature of 80 ℃, and drying to obtain a lithium carbonate product.

Example four

Collecting lithium-containing brine 5000ml, wherein Mg²⁺The content is 15g/L (0.63mol/L), KCl is 3g/L, LiCl is 20g/L, NaNO₃Is 22g/L, Li₂SO₄5g/L, (total of all auxiliaries 0.805mol/L) potassium hydroxide in a concentration of 0.5mol/L was added dropwise to the lithium-containing brine until the pH was 10 and reacted at 120 ℃ for 12 h. After the reaction is finished, carrying out solid-liquid separation, washing and drying the solid part to obtain the magnesium hydroxide nanosheet, wherein the LiCl content in the liquid phase after the solid-liquid separation is 20g/l, and the Mg content is²⁺Is 0.2 g/L. And adding ammonium carbonate with the molar mass 1.5 times that of lithium ions in the lithium-containing feed liquid into the magnesium-removed lithium-containing feed liquid at 80 ℃ to react for 2 hours, then carrying out hot filtration at 80 ℃, washing the solid obtained by filtration with deionized water at 80 ℃, and drying to obtain a lithium carbonate product.

EXAMPLE five

2000ml of lithium-containing feed liquid, wherein Mg²⁺Content of 10g/L, Li⁺The content of the solution was 15g/L (molar ratio of lithium to magnesium: 5.17), ZnCl was added₂The concentration was adjusted to 0.2g/L, hydrazine hydrate at a concentration of 1.5mol/L was added dropwise to the feed solution at a rate of 1ml/s at a rotation speed of 400rpm until the pH became 9.5 to obtain a slurry, and the slurry was then subjected to crystallization reaction at 160 ℃ for 10 hours. And after the reaction is finished, performing solid-liquid separation on the slurry, washing and drying the solid part to obtain magnesium hydroxide nanosheets, wherein the content of lithium in the liquid phase after the solid-liquid separation is 14.9g/L and the content of magnesium is 0.01g/L, adding ammonium bicarbonate with the molar mass being 2.0 times of that of lithium ions in the lithium-containing feed liquid into the magnesium-removed lithium-containing feed liquid at 80 ℃ for reaction for 2 hours, performing heat filtration at 80 ℃, washing the filtered solid by deionized water at 80 ℃, and drying to obtain a lithium carbonate product.

EXAMPLE six

500ml of lithium-containing feed solution, wherein Mg²⁺The content was 12g/L, the Li + content was 5g/L (molar ratio of lithium to magnesium was 1.43), Co (NO) was added₃)₂Make it to be concentrated0.5g/l, 1mol/l sodium hydroxide was added dropwise to the feed solution at a rate of 1ml/s at a rotation speed of 350rpm until the pH became 10 to give a slurry, which was then crystallized at 130 ℃ for 16 hours. And after the reaction is finished, performing solid-liquid separation on the slurry, washing and drying the solid part to obtain magnesium hydroxide nanosheets, wherein the lithium content in the liquid phase after the solid-liquid separation is 4.88g/l, and the magnesium content is 0.05g/l, adding sodium carbonate with the molar mass 1.2 times that of lithium ions in the lithium-containing feed liquid into the magnesium-removed lithium-containing feed liquid at 80 ℃ for reaction for 2 hours, performing heat filtration at 80 ℃, washing the filtered solid with deionized water at 80 ℃, and drying to obtain a lithium carbonate product.

The invention has been described in an illustrative manner, and it is to be understood that any simple variations, modifications or other equivalent changes which can be made by one skilled in the art without departing from the spirit of the invention fall within the scope of the invention.

Claims (8)

1. A preparation method for preparing lithium carbonate and co-producing magnesium hydroxide nanosheets from feed liquid containing lithium and magnesium is characterized by comprising the following steps:

step 1, adjusting the pH value of a lithium-containing and magnesium-containing stock solution to 7.2-13.5, and reacting at the reaction temperature of 40-180 ℃ for 0.5-24 h to obtain magnesium precipitate slurry;

step 2, carrying out solid-liquid separation on the magnesium precipitation slurry obtained after the step 1 is finished, washing and drying a solid part to obtain a magnesium hydroxide nanosheet, and obtaining a lithium-containing feed liquid with magnesium removed from a liquid part;

step 3, adding carbonate into the lithium-containing feed liquid without magnesium obtained in the step 2, wherein the molar weight of the carbonate is 0.55-2.0 times of that of lithium in the lithium-containing feed liquid without magnesium, and reacting for 0.1-12 hours at 50-150 ℃ to obtain lithium precipitate slurry, wherein the carbonate is at least one of sodium carbonate, potassium carbonate, ammonium bicarbonate, sodium bicarbonate and potassium bicarbonate;

step 4, carrying out solid-liquid separation, washing and drying on the lithium precipitation slurry obtained in the step 3 to obtain a lithium carbonate product; the solid-liquid separation, washing and drying processes are all carried out at 50-150 ℃;

the content of magnesium ions in the feed liquid containing lithium and magnesium is 0.01-200 g/L, and the content of lithium ions is 0.01-50 g/L.

2. The preparation method according to claim 1, wherein the adjusting of the pH of the lithium and magnesium-containing feed solution to 7.2-13.5 is performed by adding an alkali solution to the pre-precipitation feed solution, wherein the alkali solution is one or more of a NaOH solution, a KOH solution, a LiOH solution, an ammonia solution, a hydrazine hydrate solution, an ammonium bicarbonate solution, a sodium bicarbonate solution, an ammonium bicarbonate solution, a hexamethylenetetramine solution or a urea solution.

3. The method according to claim 2, wherein the concentration of the alkali solution is 0.1 to 8 mol/L.

4. The preparation method according to claim 1, wherein the lithium and magnesium-containing feed liquid has a magnesium content of 0.1 to 60g/L and a lithium content of 0.1 to 40 g/L.

5. The preparation method according to claim 1, wherein the magnesium hydroxide nanosheet is 10-500 nm in particle size, 5-50 nm in thickness, and has a lamellar structure.

6. The production method according to claim 5, wherein the sheet-like structure is a hexagonal sheet-like structure.

7. The method according to claim 1, wherein the reaction temperature in step 1 is 80 to 150 ℃.

8. A preparation method for preparing lithium carbonate and co-producing magnesium hydroxide nanosheets from feed liquid containing lithium and magnesium is characterized by comprising the following steps:

step 1, adding a co-additive into a feed liquid containing lithium and magnesium, uniformly dispersing to obtain a pretreated feed liquid, adjusting the pH of the pretreated feed liquid to 7.2-13.5, and reacting at a reaction temperature of 90-130 ℃ for 0.5-24 h to obtain magnesium precipitate slurry;

the assistant is inorganic salt, the cation in the inorganic salt is at least one cation in Li, K, Na, Ca, Zn, Ni, Co or Cu, and the anion in the inorganic salt is at least one of chloride, bromide, nitrate, sulfate, borate or carbonate;

the molar ratio of the sum of the molar weight of the co-assistant cations to the magnesium ions in the pretreated feed liquid is (0.1-10): 1;

step 2, carrying out solid-liquid separation on the magnesium precipitation slurry obtained after the step 1 is finished, washing and drying a solid part to obtain a magnesium hydroxide nanosheet, and obtaining a lithium-containing feed liquid with magnesium removed from a liquid part;

step 3, adding carbonate into the lithium-containing feed liquid with magnesium removed obtained in the step 3, wherein the molar weight of the carbonate is 0.55-2.0 times of that of lithium in the lithium-containing feed liquid with magnesium removed, and reacting for 0.1-12 hours at 50-150 ℃ to obtain lithium precipitate slurry, wherein the carbonate is at least one of sodium carbonate, potassium carbonate, ammonium bicarbonate, sodium bicarbonate, potassium bicarbonate or urea;

step 4, carrying out solid-liquid separation, washing and drying on the lithium precipitation slurry obtained in the step 3 to obtain a lithium carbonate product; the solid-liquid separation, washing and drying processes are all carried out at 50-150 ℃;

the content of magnesium ions in the feed liquid containing lithium and magnesium is 0.5-30 g/L, and the content of lithium ions is 0.5-30 g/L;

the process of adjusting the pH value of the lithium and magnesium-containing feed liquid to 7.2-13.5 is realized by adding an alkali solution into the lithium and magnesium-containing feed liquid, wherein the alkali solution is one or more of a NaOH solution, a KOH solution, a LiOH solution, an ammonia water solution, a hydrazine hydrate solution, an ammonium bicarbonate solution, a sodium bicarbonate solution, an ammonium bicarbonate solution, a hexamethylenetetramine solution or a urea solution, and the concentration of the alkali solution is 0.5-5 mol/L.

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