SU654696A1 - Electrolyzer - Google Patents

Description

one

The invention relates to the field of manganese electrochemistry, namely to electrolyzers used for the electrochemical production of manganese compounds.

A known cell for the production of manganese acid, containing a corpus-core and a soluble anode and cathode located in it, separated by a porous diaphragm | .1.

Also known is an electrolytic cell comprising a housing and soluble and insoluble anodes and a cathode located therein, as well as a porous diaphragm. The porous diaphragm separates the insoluble anode from the soluble anode and cathode.

The disadvantage of these electrolyzers is the possibility of obtaining only one Product, as well as high energy consumption.

The aim of the invention is the simultaneous production of manganese acid and potassium permanganate and reduction of power consumption.

This goal is achieved by an electrolytic cell containing a housing and cathodes located therein, anodes and a porous diaphragm in which the anodes are soluble in a manganese-containing alloy and are located on both sides of the diaphragm, and the cathodes are equipped with an internal cooling system and are made of brass or copper.

Pa drawing shows a schematic diagram of the electrolyzer.

The cell consists of a housing 1, divided by a porous diaphragm 2 into two cells 3 and 4. In cells 3 and 4, soluble anodes 5 are located and brass or copper cathodes 6 are located on both sides of the anodes. Cell 3 is designed to receive potassium permanganate.

The cell 4 contains ferromanganese anodes 5, which serve for the synthesis of manganese acid.

An alkaline carbonate electrolyte is poured into both cells 3 and 4. Anode power

5 and the cathodes 6 in cell 3 effected from

power sources 7, and anode 5 and cathodes

6 in the cell 4 - from the source 8 of the power supply.

The cell operates as follows.

Using sources 7 and 8, it is possible to control the current flowing through the anodes 5. When direct current is applied to the anodes, the manganese anion is electrolyzed by oxidizing manganese. At the same time, manganic acid accumulates in cell 4, which, after reaching the required concentration, is drained, and the cell is again filled in with an alkaline carbonate solution.

In cell 3, potassium permanganate is synthesized as a result of soluble ferromanganese anodes, which crystallizes from solution during electrolysis. Two processes occur simultaneously in this cell: utilization (use) of alkali, “running in cell 4, and maintaining the concentration of alkali in cell 3 by neutralizing the manganese-acid anion with alkali.

Synthesis of manganese anion proceeds by the reaction of Mn- | -4H2Odi7e- HMnO4 + + 3.5H2. At the same time, the process of electrodialysis of potassium ion from cell 4 to cell 3 is underway. Cell 4 is enriched with manganese acid in cell 4, and cell 3 is replenished by alkali concentration due to electrodialysis, which decreases as potassium permanganate crystals are released from the solution.

The monitor is the pH meter. By adjusting the pH meter and analytical control of the solution for the content of manganese acid and potassium ion, the solutions are adjusted.

Solutions of both manganic acid and potassium permanganate are filtered off.

The proposed electrolyzer design provides:

the use of current to obtain manganese acid and potassium perganganate by using a combination of electrodialysis and anodic dissolution of manganese in one electrolyzer;

reducing the consumption of cathode material by 1.5 times due to the use of cathodes common to both processes;

reduction of electric power consumption by 2 times, due to a decrease in voltage in the bath from 10 to 5.4 V and an increase in the current output of electrolysis products by 30-45%;

the possibility of obtaining two products in one electrolysis, which ensures a reduction in the production area.

Claims (2)

1. USSR Author's Certificate No. 512667, cl. From 25B to 9/00, 1972. 2. USSR author's certificate number 417981, cl. From 25B to 9/00, 1973. ff + +