SU1507881A1 - Nonconsumable anode - Google Patents

Abstract

This invention relates to electrochemistry. The field of application is the processes of cathodic reduction of metals, for example, when coating palladium in drum baths when processing parts in bulk. The purpose of the invention is to increase the technological capabilities by ensuring the stability of the current mode at various cathode surfaces. The insoluble anode is made of a microporous ceramic vessel 1, the micropores 2 of which are partially filled with graphite 3 and electrolyte metal 4 5. A graphite rod 8 and an electrically conductive solution 9 are placed in a ceramic vessel during use. The anode prevents the decomposition of organic composite electrolyte. 1 hp f-ly, 3 ill.

Description

SP vi

QO 00

This invention relates to electrochemistry, in particular to insoluble anodes.

The field of application is the cathodic reduction of metals, for example, for coating palladium in drum baths when processing parts in bulk.

The purpose of the invention is to increase the technological capabilities by ensuring the stability of the current mode at various cathode surfaces.

FIG. 1 shows an insoluble anode; in fig. 2 - insoluble anode with a bipolar operating system; in fig. 3 - cross section of the wall of the insoluble anode.

The insoluble anode consists of a microporous ceramic vessel 1, the micropores 2 of which are partially filled with graphite 3 and metal 4 of the electrolyte 5 used. A metal ring 6 is fixed to the metal ring 6 with metal hooks 7.

The insoluble anode for a bipolar operating system consists of a microporous ceramic vessel 1, micropores 2 of which are partially filled with graphite 3 and metal 4 of the electrolyte 5. The metal ring 6 is fixed to the vessel 1 with metal hooks 7 that are insulated. A graphite rod 8, fitted with a metal hook 7 for hanging onto the anode rod of the bath, is placed inside the vessel 1 and the electrically conductive solution 9 is poured.

Insoluble anode works as follows.

The microporous ceramic vessel 1 is immersed in the bis electrolyte using metal hooks 7 and is hung on the anode rod of the bath, to which the voltage is applied. An electrical circuit is created: a current source, anodic bath shtang, metal hooks 7, ring 6, graphite 3, partially filling micropores 2, electrolyte 5, the part to be coated. Its advantages over the purely graphite anode are the following: the organic component of the electrolyte is not oxidized, the electrolyte is not contaminated with particles of graphite anode, and a stable current regime is ensured at various cathode surfaces.

The insoluble anode with a bipolar operating system works as follows.

Microporous ceramic vessel 1 s

a graphite rod 8 placed inside it and an electrically conductive solution 9 poured inside it are placed in electrolyte 5 and a graphite rod 8 is attached to a voltage source, while the microporous ceramic vessel 1 is isolated from the voltage source. An electrical circuit is created: a current source, anodic pole, a graphite rod 8, an electrically conductive solution 9, particles of graphite 3 and

metal 4 in micropores 2, electrolyte 5, the part to be coated. Since ceramic vessel 1 due to the partial filling of its micropores 2 with graphite 3 and metal 4 of electrolyte 5 is a conductive material, when placed in the electric field of the bath, it is polarized and it works as an insoluble anode. The advantages of the system compared with the prototype: the organic component of the electrolyte is not oxidized, it is not contaminated

graphite particles electrolyte, provides a stable current mode at different cathode surfaces, provides an increase in the anode surface due to the penetration of additional particles of graphite into the free micropores of ceramics

cheskogo vessel.

Claims (2)

1. An insoluble anode, mainly for electroplating electrolyte coatings, comprising a housing with a graphite element, characterized in that, in order to increase technological capabilities by ensuring the stability of the current mode at different cathode surfaces, the housing is made in the form of a microporous ceramic vessel, micropores of which are partially filled with graphite and electrolyte metal. 2. Anode according to claim 1, characterized in that it is provided with a graphite rod and an electrically conductive solution placed inside the housing. FIG. / Fig.Z