The problem of improving the efficiency of chemical milling technologies while simplifying the procedure for their implementation remains unresolved. One of the efficient ways to solve this problem is to develop new etching compounds. The purpose of this work was to experimentally determine the optimal conditions for the use of salt additives (NaNO₃, NaClO₄) as components of alkaline solutions in chemical milling technologies, as well as to develop the foundations for the rational use of waste in these technologies. It is shown that the introduction of a salt additive to an alkaline solution of chemical milling increases the rate of aluminium removal. In this case, the quality of the treated surface is improved, and the amount of evolved hydrogen decreases. The optimal chemical composition of the etching solution is proposed. It is shown that the spent aluminate solutions can be used to obtain the basic aluminium salt A1₂(OH)₅C1, which has a high coagulating ability. It has been determined that aluminium hydroxychloride can be used as a precipitating reagent for the decomposition of alkali-aluminate solutions. The scheme of the chemical milling process has been proposed. It provides for the regeneration of the components of the etching alkaline solution and contributes to the rational use of technological resources

Key words: chemical milling, aluminium and its alloys, alkaline solution, salt additive, dissolution speed.

Zaltsman L.G., Chornaya S.M. Electroplating satellite. Kiev, Tekhnika, 1989. 191 p.

Çakir O. Etchants for chemical machining of aluminium and its alloys. Acta Phys. Polonica A, 2019, v. 135, рр. 586-587.

Shapovalov S.A., Larin V.I., Krasnopyorova A.P. Complex formation and association in the solutions with the participation of metal particles, functional and dyes: practical solutions and implementation. Kharkiv, KhNU imeni V.N. Karazina, 2018. 148 p.

Lukashuk T.S., Larin V.I. Anodic and corrosive behavior of aluminum in sodium hydroxide solutions containing polyethylene glycols. Bulletin of NTU «KhPI». Chemistry, chem. technol. and ecology. 2007, no. 27, p. 83-87.

Larin V.I., Lukashchuk T.S., Bakumenko O.M. Dissolution of aluminum in water-alcohol solutions of alkalis. Ukr. Chem. Zhurn., 2008, no. 7, pp. 37-41.

Okorokova N.S., Platonov A.A., Pushkin K.V., Sevruk S.D., Farmakovskaya A.A. Modification of the reaction products of anodic oxidation of aluminum during the operation of an air-aluminum chemical current source with a salt electrolyte to improve its operational characteristics. Metal Technology, 2013, no. 1, pp. 15-21.

Larin V.I., Lukashchuk T.S., Pshenichna S.V. Electrochemistry and passivation of aluminium in water and water-organic areas of alkalis. Nauk. Visnik of Chernivetskiy University, 2008, no. 399-400, pp. 122-124.

Rendón M.V., Calderón J.A. Evaluation of the corrosion behavior of the Al-356 alloy in NaCl solutions. Quim. Nova, 2011, №7, рр. 1163-1166.

Li Q., Wang J., Hu W. Optimizations of electric current assisted chemical milling condition of 2219 aluminum alloy. J. Materials Process. Technol., 2017, v. 249, рр. 379-385.

Grigorieva I.O., Dresvyannikov A.F. Anodic and corrosion behavior of aluminum in nitrate-containing electrolytes. Bulletin Kazan. Technological University, 2012, №7, рр. 275-278.

Samoilov Y.O., Shapovalov S.A., Larin V.I. Measurement of temperature effects of electrochemical reactions on polarization between "electrode - solution" in the Cu-CuSO4-H2O system. Visnyk KhNU, 2008, no. 820, рр. 350-353.

Lukashchuk T.S., Larin V.I., Pshenichna S.V. Corrosion behaviour of aluminium in chloride solutions of different composition. Problems of corrosion and corrosion protection of materials [Lviv]. 2014, №10, pp. 110-114.

https://doi.org/10.35546/kntu2078-4481.2020.3.6