Study of the influence of acoustic oscillations on the structure and wear resistance of deposited alloys of the Fe-Cr-Ni-Mn-Mo-Ti-Nb-C system

The effect of ultrasonic vibrations on the structural-phase composition and wear resistance of hypoeutectic and hypereutectic surfacing alloys of the Fe–Cr–Ni–Mn–Mo–Ti–Nb–C system was studied. Vibrations were introduced into the weld pool using a filler flux-cored wire during electric arc surfacing with a consumable electrode. Metallographic studies of the alloys, micro-X-ray spectral and X-ray structural analyses were performed. Alloy samples were tested for resistance to gas-abrasive wear, as well as wear through an abrasive layer at normal and elevated temperatures up to 600°C. It was found that acoustic treatment of the weld pool, differently affecting the structure of the alloys of the alloying system under consideration, can cause both a decrease and an increase in the wear resistance of the alloys.

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