RU2505891C1 - Electrolyte for chemical current source - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to power engineering, particularly to preparation of compositions which contain lithium fluoride, bromide and molybdate, where in order to widen the range of concentrations with a low melting point, lithium tungstate is added, with the following ratio of components, wt %: lithium fluoride 6.34-7.03, lithium bromide 76.28-79.61, lithium tungstate 4.85-9.59, lithium molybdate 4.47-11.84.

EFFECT: composition ensures operating capacity of electrolyte of a chemical current source with a relatively wide range of concentration of components.

1 tbl, 6 ex

Description

The invention relates to the field of energy, in particular to the development of compositions used as molten electrolytes for chemical current sources.

Electrolyte compositions for chemical current sources are known. The first includes lithium fluoride (8.19 wt.%) And lithium bromide (91.81 wt.%) (Diagrams of the fusion of salt systems. Part III. Binary systems with a common cation. Reference. Posypayko VI, Alekseeva A. A., Vasina N.A. M.: Metallurgy, 1979, 204 pp.). The operating temperature of the composition is above 467 ° C. The second includes lithium fluoride (7.02 wt.%), Lithium bromide (79.48 wt.%) And lithium tungstate (13.50 wt.%) (Egortsev G.E., Garkushin I.K., Istomova M. A. Phase equilibria and chemical interaction in systems with the participation of alkali metal fluorides and bromides. Ekaterinburg: Ural Branch of the Russian Academy of Sciences, 2008. 132 p.). The operating temperature of the composition is above 456 ° C.

The closest to the claimed composition in terms of temperature and components is a low-melting composition, including lithium fluoride (5.50 wt.%), Lithium bromide (73.94 wt.%) And lithium molybdate (20.56 wt.%) (Frolov E. I., Gubanova T.V., Garkushin I.K., Afanasyeva O.Yu. Three-component systems LiF-LiBr-Li ₂ MoO ₄ and LiF-LiBr-Li ₂ SO ₄ // Izvestiya VUZov. Chemistry and Chemical Technology. - 2009. T. 52. - No. 12. - S.129-131). The operating temperature of the composition is above 444 ° C. However, this is a clearly fixed composition corresponding to the point of invariant equilibrium - eutectic.

The present invention provides operation in the temperature range above 447-451 ° C as a meltable electrolyte with a wide range of concentrations of the starting components.

The novelty of the claimed composition compared with the known lies in the fact that the electrolyte additionally contains lithium tungstate in the following ratio of components, wt.%:

lithium fluoride 6.34 ... 7.03

lithium bromide 76.28 ... 79.61

lithium tungstate 4.85 ... 9.59

lithium molybdate 4.47 ... 11.84

Examples of specific performance

Example 1

In a shaft-type electric furnace, anhydrous salts of the qualification “chda” (LiF), “hch” (LiBr), “h” (Li ₂ WO ₄ ) and “chda” (Li ₂ MoO ₄ ) are remelted in the following ratio: 0.0703 g ( 7.3 wt.%) Lithium fluoride + 0.628 g (76.8 wt.%) Lithium bromide + 0.485 g (4.85 wt.%) Lithium tungstate + 0.184 g (11.84 wt.%) Lithium molybdate.

The melting point of the mixture is 447 ° C.

Example 2

In the conditions of example 1, anhydrous salts are remelted in the following ratio: 0.068 g (6.80 wt.%) Lithium fluoride + 0.813 g (78.13 wt.%) Lithium bromide + 0.686 g (6.86 wt.%) Lithium tungstate + 0.0821 g (8.21 wt.%) Lithium molybdate.

The melting point of the mixture is 447 ° C.

Example 3

In the conditions of example 1, anhydrous salts are remelted in the following ratio: 0.0634 g (6.34 wt.%) Lithium fluoride + 0.7961 g (79.61 wt.%) Lithium bromide + 0.0959 g (9.59 wt. .%) lithium tungstate + 0.0447 g (4.47 wt.%) lithium molybdate.

The melting point of the mixture is 451 ° C.

Beyond the claimed limits, the single-phase composition is violated, which leads to an increase in the melting temperature.

Example 4

In the conditions of example 1, anhydrous salts are remelted in the following ratio: 0.1643 g (16.43 wt.%) Lithium fluoride + 0.6973 g (69.73 wt.%) Lithium bromide + 0.0311 g (3.11 wt. .%) lithium tungstate + 0.1074 g (10.74 wt.%) lithium molybdate.

The melting point of the mixture is 603 ° C.

Example 5

In the conditions of example 1, the anhydrous salts of qualification are remelted in the following ratio: 0.1626 g (16.26 wt.%) Lithium fluoride + 0.7023 g (70.23 wt.%) Lithium bromide + 0.0615 g (6.15 wt.%) lithium tungstate + 0.0736 g (7.36 wt.%) lithium molybdate.

The melting point of the mixture is 600 ° C.

Example 6

In the conditions of example 1, anhydrous salts are remelted in the following ratio: 0.1613 g (16.13 wt.%) Lithium fluoride + 0.7128 g (71.28 wt.%) Lithium bromide + 0.0854 g (8.54 wt. .%) lithium tungstate + 0.0405 g (4.05 wt.%) lithium molybdate.

The melting point of the mixture is 598 ° C.

The table shows the comparative characteristics of the properties of the claimed composition and composition, selected as a prototype.

The composition of the mixture, wt.% Melting point, ° С Compositions LiF LiBr Li ₂ MoO ₄ Li ₂ WO ₄ Prototype 5.50 73.94 20.56 444 Proposed one 7.03 76.28 11.84 4.85 447 2 6.80 78.13 8.21 6.86 447 3 6.34 79.61 4.47 9.59 451

As can be seen from the table, the proposed composition ensures the operation of a chemical current source in the temperature range above 447-451 ° C with a wide range of concentrations of the starting components.

Claims (1)

An electrolyte for a chemical current source, including lithium fluoride, bromide and molybdate, characterized in that lithium tungstate is additionally introduced in order to expand the concentration range with a low melting point in the following ratio, wt.%:
lithium fluoride 6.34 ... 7.03
lithium bromide 76.28 ... 79.61
lithium tungstate 4.85 ... 9.59
lithium molybdate 4.47 ... 11.84