INFLUENCE OF 3D PRINTING PARAMETERS OF ALUMINUMMANGANESE BRONZE BY WIRE-ARC ADDITIVE MANUFACTURING ON THE MICROSTRUCTURE AND MECHANICAL PROPERTIES

The paper studies the influence of wire-arc additive manufacturing process parameters of aluminum-manganese bronze Cu[Al.sub.9][Mn.sub.2] products on the structure and mechanical properties of samples The microstructure of aluminum bronze is defined by the presence of [alpha]-Cu(Al) solid solution and residual martensitic [beta]-phase of [Cu.sub.3]Al. Insignificant anisotropy of mechanical properties of the samples cut in sections parallel and perpendicular to the direction of printing has been revealed. Samples cut in the cross section parallel to the printing direction show the highest values of the tensile strength and less ductility compared to the samples cut in cross section perpendicular to the printing direction. The tensile strength values vary from 515 MPa to 591 MPa between blades cut along and across the ply application. The strength of the hot-rolled product (440 MPa) is 25% lower than the strength of the product obtained by the WAAM method (591 MPa). It is shown that a change in the heat input does not affect the average width of the dendritic grains in the cross section perpendicular to the printing direction. It was found that changing the printing mode can lead both to an increase in the mechanical properties of the samples and to violations of the geometry of the obtained samples. Keywords: aluminum-manganese bronze, wire-arc additive manufacturing, heat deposition, microstructure, mechanical properties, anisotropy.