In industry copper powder is recieved under constant DC. Surface roughening occurs during evolution of the dendritic particles. It is suggested to create a new impulse of current equal to the initial current density of 3200 A/m² in order to obtain uniform structure of the precipitate. Current load was evaluated by the result of chronopotentiometry research of the dynamics of the dendritic precipitate on cylindrical electrode. Four-impulse galvanostatic electrolysis was investigated for the copper powder GG. New current impulse shifts the electrode potential to the cathodic area, crystallization process flows more rapidly.

electrolytic metal powders; powder metallurgy; copper powder

Neikov O, Naboychenko S. Handbook of non-ferrous metal powders: Technologies and applications. Naboychenko S, Mourachova I, Gopienko V, Frishberg I, Lotsko D, editors. Amsterdam: Elsevier; 2009. 634 p. ISBN: 978-1-85617-422-0.

Murashova IB, Darintseva AB, Rudoi VM. Analysis of growth dynamics of dendrite copper deposit in copper sulfate solutions under the galvanostatic conditions. Russ J Electrochem. 2010;46(6):611-8. doi:10.1134/S1023193510060030

Murashova IB, Sokolovskaya EE, Lebed' AB, Yun' AA, Bodrova ML. Tsvetnye metally. 2007;10:46. Russian.

Darintseva AB, Osipova ML, Murashova IB. Regulirovanie struktury dendritnogo mednogo osadka GG v khode ego elektroliza izmeneniem katodnoy poverkhnosti elektrolizera. Vestnik Kazanskogo Tekhnologicheskogo Universiteta. 2012;13:129-33. Russian.

Ksenzhek OS, Shembel' EM, Kalinovskiy EA, Shustov VA. Elektrokhimicheskiye protsessy v poristykh matritsakh [Electrochemical processes in porous matrix]. Kiev (Ukraine): Vysshaya shkola; 1983. 220 p. Russian.