RU2519194C2 - Method of obtaining lithium tetrafluoroborate - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention can be used in chemical industry. Method of obtaining lithium tetrafluoroborate includes addition of lithium borohydrate in tetrahydrofuran into liquid hydrogen fluoride at temperature (-57)-(-53)°C. Solvent is removed in vacuum at temperature 100-105°C. Reaction mass is kept at said temperature for 4 hours with residual pressure 0.03 mm Hg.

EFFECT: invention makes it possible to increase output of target product and its purity.

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Description

The present invention relates to a technology for the production of electrolytes of chemical sources as a catalyst for polymerization reactions.

A known method of producing lithium tetrafluoroborate, including the interaction of lithium fluoride with gaseous boron trifluoride. The process is carried out in the presence of fluorine at a volume ratio of boron trifluoride and fluorine of 1: 0.05-0.2 under a pressure of 0.35-2.50 MPa and at a temperature of 70-250 ° C (see patent SU No. 1655083 IPC C01B 35/06, C01D 15/00).

The main disadvantage of this method is the lack of purity of the finished product.

A known method of producing lithium tetrafluoroborate, including the interaction of lithium fluoride with gaseous boron trifluoride at elevated temperature. The process is conducted in a molten lithium tetrafluoroborate at a temperature of 400-420 ° C at a boron trifluoride pressure of 0.2-2.5 MPa (see SU patent No. 1785199 IPC C01D 15/00, C01B 35/12).

The main disadvantage of this method is the significant presence of water in the finished product, the removal of which additionally requires a drying process.

The closest set of essential features to the proposed method is a method for producing lithium tetrafluoroborate by reacting lithium salt with boron trifluoride in tetrahydrofuran medium, followed by removal of the solvent in vacuum, washing the product with ether and drying it at elevated temperature. In this case, the interaction is carried out at a temperature of 15-25 ° C, passing boron trifluoride through a suspension of lithium fluoride in a solvent (see patent SU No. 1013405 IPC C01B 35/06).

The main disadvantages of this method are the low yield and insufficient purity of the finished product.

The aim of the present invention is to increase the yield of the target product and its purity.

This goal is achieved by the fact that in the method for producing lithium tetrafluoroborate, which involves the interaction of a lithium salt with a fluorine compound in tetrahydrofuran medium with its subsequent removal in vacuum, its borohydride is used as a lithium salt, hydrogen fluoride is used as a fluorine compound, the interaction is carried out at a temperature ( -57) - (- 53) ° C,adding a solution of lithium borohydride to liquid hydrogen fluoride, and the removal of solvent is carried out in vacuum, heating the product to a temperature of 100-105 ° C and incubating for 4 hours at a residual pressure of 0.03 mm Hg

A distinctive feature of the claimed invention is that its borohydride is used as a lithium salt, hydrogen fluoride is used as a fluorine compound, the reaction is carried out at a temperature of (-57) - (-53) ° C, adding a solution of lithium borohydride to liquid hydrogen fluoride, and solvent removal is carried out in vacuum, heating the product to a temperature of 100-105 ° C and holding for 4 hours at a residual pressure of 0.03 mm Hg

Example. The method is as follows. 85 g of hydrogen fluoride are condensed in a Teflon reactor, the contents are cooled to a temperature of (-57) - (-53) ° C. Then, for 3.5 hours, with stirring and cooling, a solution of LiBH ₄ (21.8 g) in tetrahydrofuran (250 ml) is dosed into the reactor. At the end of the process, the reaction mass is stirred for 2 hours with a gradual increase in temperature to 18-22 ° C. The reactor was then evacuated and the solvent was distilled off by increasing the temperature to 100-105 ° C. At this temperature, the reaction mass is maintained for 4 hours at a residual pressure of 0.03 mm Hg. Yield LiBF ₄ 93.60 g (99.85%).

LiBH ₄ + 4HF = LiBF ₄ + 4H ₂

The use of lithium borohydride as a lithium compound makes it possible to remove hydroxyl-containing impurities at the beginning of the process and subsequently, using lithium tetrafluoroborate, to eliminate the stage of drying and absolute.

The lower limit of the temperature range of the cooling of hydrogen fluoride T = -57 ° C due to maintaining the necessary reaction rate with LiBH_four and a decrease in the exoeffect of the process.

The upper limit of the temperature range of the cooling of hydrogen fluoride T = -53 ° C is selected in order to reduce evaporation of the solvent and contamination of the product.

The lower limit of the temperature range of the product heating T = 100 ° C is due to the saturated vapor pressure of the solvent with impurities contained in it and is sufficient for its distillation from the product.

The upper limit of the product heating temperature T = 105 ° C is due to the inadmissibility of the formation of new reactions with the production of impurities that adversely affect the purity of the finished product.

The residual pressure of the holding product P = 0.03 mm Hg due to the creation of a pressure gradient necessary to more completely remove the solvent and increase the purity of the product.

Claims (1)

A method of producing lithium tetrafluoroborate, including the interaction of a lithium salt with a fluorine compound in tetrahydrofuran medium with its subsequent removal in vacuum, characterized in that, in order to increase the yield of the product and its purity, its borohydride is used as the lithium salt, and fluoride is used as the fluorine compound hydrogen, and the interaction is carried out at a temperature of (-57) - (-53) ° C, adding a solution of lithium borohydride to liquid hydrogen fluoride, while the solvent is removed in vacuum, heating the product to a temperature of 100-105 C and soaking 4 hours at a residual pressure of 0,03 mm Hg