SU39751A1 - The method of obtaining organosols of alkali metals - Google Patents

Description

The immense technical value of alkali metals as catalysts in. A number of organic syntheses, for example, in the synthesis of artificial rubber, etc., rests in the absence of successful methods for their introduction and a uniform distribution throughout the volume of the external space. The most successful is the introduction of an alkali metal in the form of a colloidal solution in one of the substances participating in the reaction or in a neutral solvent with respect to this reaction.,

The use of colloidal catalysts, however, has not received sufficient distribution so far due to the lack of technically successful methods for the preparation of alkali metal organosols. The Svedberg method, due to its complexity, low productivity and quality of results (charring of solvent) cannot count on technical development.

The method developed by the authors for the preparation of colloidal solutions is characterized by simplicity, productivity

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And the high quality of the products obtained.

Highly concentrated sols make it possible to obtain metal vapor in the liquid. The introduction of metallic vapor into a liquid can be accomplished in various ways, for example, by placing a tube connected to an oven containing this metal under the liquid level at a temperature that ensures a sufficiently high elasticity of metallic vapors. Particularly successful was the introduction of metal vapor in the path, heating the metal inside the high-frequency liquid. At the same time, the surface of the molten metal is surrounded by a vapor barrier of the solvent, where the metal vapor condenses.

To obtain colloidal sodium in the laboratory, instruments have been designed, shown schematically in FIG. 1 and 2.

Example 1. The method of the experiment was as follows. The device was filled with xylene, etc. to such a level that the stove nozzle 6 entered into a liquid of 3-5 mm. It was inserted on the lubricant section 2, carrying the sodium bake, and the cooling device was pumped out with an oil pump, after which the current into the heating furnace winding. At the same time, air bubbles and overheated xylene vapor were squeezed out of the furnace nozzle at first, and when the temperature reached 440-600, sodium vapor condensed in the liquid began to bubble. With this, at the very beginning of the process, separate red streams are seen, but further the formation of the colloid goes very quickly and within a few minutes the concentrations become so large that the sol becomes completely opaque. Upon reaching the desired concentration, sol turned the device into a vial 5, which was soldered to the device, which were sealed off without air access. The resulting sols were highly concentrated and were stable. Example 2. Production of sodium ashes in butadiene and in other solvents using a high frequency furnace is carried out in laboratories in special ampoules of the type shown in FIG. 2, a piece of sodium was placed in the mounted on the stem of the glands | 1st box 1, and the ampoule after pouring the butadiene and pumping out during cooling was sealed off without air. The cooled ampoule was inserted into a helix of a high-frequency furnace, where for about 10-15 seconds. sodium dispersion occurred. strongly dispersed, and butadiene formed a bag of vapors near the box, in which the vapor of sodium co-condensate () was condensed. Butadiene vapors bubbled the liquid and carried the sol by volume. stable at low temperatures. As the temperature approaches room temperature, the butadiene polymerizes. alkali metal by dispersing the metal in an organic liquid, characterized in that the alkali metal vapor in a separate heated vessel ;; is introduced into the organic liquid. characterized in that the alkali metal is placed in an organic liquid and heated by high-frequency currents. Iron box and sodium in this way. The sols thus obtained are the subject of the invention. 1. A method for producing organosols 2. A variation of the method according to claim 1,