阅读说明：本技术 一种铝电解槽用氟化铝的制备方法 (Preparation method of aluminum fluoride for aluminum electrolysis cell ) 是由 吕晓军 邹忠 王维维 于 2020-06-28 设计创作，主要内容包括：本发明涉及一种铝电解槽用氟化铝的制备方法。先将富锂钾铝电解质浸出液加碱调节PH,并控制Al<Sup>3+</Sup>、F<Sup>-</Sup>、OH<Sup>-</Sup>比例进行沉淀反应,反应温度为20~110℃,反应时间20~120min,得到一定量的沉淀,所得沉淀产物在350~650℃煅烧1~3h,即可得到无水氟化铝。本发明通过加碱并控制Al<Sup>3+</Sup>、F<Sup>-</Sup>、OH<Sup>-</Sup>比例获得羟基氟化铝,再通过煅烧处理,获得氟化铝,最高能同时回收Al<Sup>3+</Sup>90wt%、F<Sup>-</Sup>90 wt%以上,该过程不引入其他杂质,碱金属损失率低,操作简单,为后续沉锂做准备,处理成本低。(The invention relates to a preparation method of aluminum fluoride for an aluminum electrolytic cell. Firstly, adding alkali into lithium-potassium-rich aluminum electrolyte leaching solution to adjust the pH value, and controlling Al 3+ 、F ‑ 、OH ‑ And (3) carrying out precipitation reaction according to the proportion, wherein the reaction temperature is 20-110 ℃, the reaction time is 20-120min, a certain amount of precipitate is obtained, and the obtained precipitate product is calcined at 350-650 ℃ for 1-3h, so that the anhydrous aluminum fluoride can be obtained. The invention adds alkali and controls Al 3+ 、F ‑ 、OH ‑ Obtaining hydroxyl aluminum fluoride according to the proportion, and then obtaining aluminum fluoride through calcination treatment, wherein Al can be recovered at the same time at the highest 3+ 90wt%、F ‑ More than 90wt%, no other impurities are introduced in the process, the loss rate of alkali metal is low, the operation is simple, preparation is made for subsequent lithium precipitation, and the treatment cost is low.)

1. A preparation method of aluminum fluoride for an aluminum electrolytic cell is characterized by comprising the following steps:

s1, providing lithium-potassium-rich aluminum electrolyte leachate;

wherein F in the lithium potassium-rich aluminum electrolyte leaching solution^-、Al³⁺In a molar ratio of 1 to 3: 1;

s2, adding alkali or alkali liquor into the lithium-potassium-rich aluminum electrolyte leaching solution in the S1 to enable F in the solution^-、Al³⁺、OH^-In a molar ratio of 1 to 3: 1: 1-3, stirring for 20-120min, and filtering to obtain filtrate and filter residue;

and S3, calcining the filter residue obtained in the S2 to obtain the aluminum fluoride.

2. The method according to claim 1, wherein in S1, F is contained in the leachate of the Li-K-rich aluminum electrolyte^-、Al³⁺In a molar ratio of 1.5-2: 1.

3. the method according to claim 1, wherein in S1, the Li-K-rich aluminum electrolyte leachate comprises an acidic leachate of Li-K-rich aluminum electrolyte and/or an inorganic salt leachate of Li-K-rich aluminum electrolyte.

4. The method according to claim 2, wherein in S2, alkali or alkaline solution is added to the leachate of lithium-potassium-rich aluminum electrolyte in S1 to make F in the solution^-、Al³⁺、OH^-In a molar ratio of 1.5-2: 1: 1.2-2.

5. The method of claim 1, wherein in S2, the base comprises NaOH, KOH, Ca (OH)₂、Na₂CO₃One or more of (a).

6. The method according to claim 1, wherein the temperature of the solution in S2 is controlled to be 20 to 110 ℃.

7. The method according to claim 1, wherein in S2, stirring is performed for 50-100 min.

8. The method as claimed in claim 1, wherein the calcination temperature in S3 is 350-650 ℃.

9. The method according to claim 1, wherein the calcination time in S3 is 1-3 h.

Technical Field

The invention relates to a preparation method of aluminum fluoride for an aluminum electrolytic cell, belonging to the field of metallurgy.

Background

Bauxite is mainly distributed in Shanxi, Henan, Guangxi, Guizhou and other places in China, alumina is produced from the bauxite, the alumina is used as an important raw material for electrolytic aluminum, the consumption of the alumina is continuously increased, originally few high-quality bauxite in China is exhausted, and most enterprises have to exploit and utilize the medium-low-quality bauxite in large quantities to produce the alumina. However, alumina produced from medium-low quality bauxite contains various impurity elements such as Li, K, etc. The lithium content in the alumina produced in many regions exceeds 0.03 percent, generally the alumina content exceeds 0.03 percent, the alumina is called lithium-rich alumina, and according to related research and research, the domestic lithium-rich alumina yield accounts for more than 60 percent of the total yield. After the aluminum oxide containing Li and K enters the aluminum electrolytic cell, elements such as Li and K are continuously accumulated in the aluminum electrolyte, and lithium salt in the electrolyte is continuously accumulated because the lithium income (lithium in the aluminum oxide) is greater than the lithium expenditure (lithium in aluminum liquid, lithium in a cell body, lithium in a furnace wall and the like), and the content of the lithium salt generally increases along with the increase of the cell age. For this reason, some aluminum electrolysis enterprises scoop lithium-potassium-rich aluminum electrolyte from the electrolytic cell and replenish fresh electrolyte in order to reduce the lithium salt content in the electrolytic cell, which results in a large amount of lithium-potassium-rich aluminum electrolyte.

For recycling waste lithium-potassium-rich aluminum electrolytes, the Chinese patent specification CN105293536A selects inorganic acid leaching in the treatment process, the Chinese patent specification CN105543504B selects roasting pretreatment before inorganic acid leaching, the patent 201910609881X selects heat treatment before inorganic salt leaching, and leachate is directly used for lithium precipitation after impurity removal, but the leachate contains a large amount of Al and F resources and is not recycled, so that not only can the resource waste be caused, but also the lithium precipitation link in the next step can be influenced if the leachate is not effectively treated. Therefore, how to recover Al and F is particularly important in the leaching solution of the existing lithium-potassium-rich aluminum electrolyte.

Disclosure of Invention

Aiming at the defects of the prior art, the invention aims to provide a preparation method of aluminum fluoride for an aluminum electrolytic cell, which utilizes lithium-potassium-rich aluminum electrolyte leachate to provide an aluminum source and a fluorine source to produce an aluminum fluoride raw material.

In order to solve the technical problems, the technical scheme of the invention is as follows:

a preparation method of aluminum fluoride for an aluminum electrolytic cell comprises the following steps:

s1, providing lithium-potassium-rich aluminum electrolyte leachate;

wherein F in the lithium potassium-rich aluminum electrolyte leaching solution^-、Al³⁺In a molar ratio of 1 to 3: 1;

s2, adding alkali or alkali liquor into the lithium-potassium-rich aluminum electrolyte leaching solution in the S1 to enable F in the solution^-、Al³⁺、OH^-In a molar ratio of 1 to 3: 1: 1-3, stirring for 20-120min, and filtering to obtain filtrate and filter residue;

and S3, calcining the filter residue obtained in the S2 to obtain the aluminum fluoride.

Further, in S1, F in the leaching solution of lithium potassium-rich aluminum electrolyte^-、Al³⁺In a molar ratio of 1.5-2: 1.

further, the lithium potassium aluminum electrolyte rich leachate comprises an acid leachate of lithium potassium aluminum electrolyte and/or an inorganic salt leachate of lithium potassium aluminum electrolyte.

Further, in S1, the lithium potassium-rich aluminum electrolyte leachate includes one or more of a lithium potassium-rich aluminum electrolyte acidic leachate, an inorganic salt leachate, a pretreated acidic leachate, and a pretreated inorganic salt leachate.

Further, in S2, adding alkali or alkaline solution into the lithium potassium-rich aluminum electrolyte leaching solution in S1 to enable F in the solution^-、Al³⁺、OH^-In a molar ratio of 1.5-2: 1: 1.2-2.

Further, in S2, the base includes NaOH, KOH, Ca (OH)₂、Na₂CO₃One or more of (a).

Further, in S2, the temperature of the solution is controlled to be 20-110 ℃, and optionally, the solution is stirred for 50-100 min.

Further, in S3, the calcination temperature is 350-650 ℃, and optionally, the calcination time is 1-3 h.

The method has wide application range, firstly leads aluminum and fluorine to be precipitated in the form of hydroxyl aluminum fluoride by regulating and controlling the pH value of the leaching solution, then calcines the precipitate to obtain the aluminum fluoride, has short flow, recycles Al and F elements, and realizes resource utilization.

Compared with the prior art, the invention has the following technical advantages:

(1) by adding alkali and controlling Al³⁺、F^-、OH^-The aluminum hydroxyfluoride is recycled in proportion, and Al can be recycled at the same time at the highest³⁺90wt%、F^-More than 90wt%, no other impurities are introduced in the process, the loss rate of alkali metal is low, the operation is simple, preparation is made for subsequent lithium precipitation, and the treatment cost is low.

(2) The hydroxy aluminum fluoride is transformed into aluminum fluoride at a certain temperature, the recovery rate is high, and other substances are not required to be added.

(3) The invention provides the lithium-potassium-rich aluminum electrolyte leachate for recycling hydroxyl aluminum fluoride and producing aluminum fluoride, provides a new idea for recycling the waste aluminum electrolyte, solves the technical problem that Al and F in the leachate cannot be effectively utilized, improves the economic benefit and promotes the stable production of aluminum electrolysis enterprises.

(4) The aluminum fluoride obtained by the method has high purity and can be directly used for the production of aluminum electrolysis cells.

Drawings

FIG. 1 is XRD patterns of precipitation products obtained by lithium potassium-rich aluminum electrolyte leachate under different pH conditions.

FIG. 2 is an XRD pattern of a precipitated product of aluminum hydroxyfluoride after calcination.

Detailed Description

The present invention will be described in detail below with reference to the embodiments with reference to the attached drawings. It should be noted that the embodiments and features of the embodiments may be combined with each other without conflict.