Aeronautical and Space-Rocket Engineering
Аuthors
1*, 21. United Engine Corporation, Moscow, Russia
2. Moscow Machine Building Enterprise named after V.V.Chernyshev, 7, Vishnevaya St., Moscow, 125362, Russia
*e-mail: kirillerikov96@gmail.com
Abstract
The article considers the modes of the machining by pulsed electron beams effect on the surface roughness and micro-hardness of the samples from the CoCrMo system alloy obtained by the additive technologies. The authors formulated the basic disadvantages of conventional production and post-production methods, which lies in the fact that billets from cobalt-chromium allows are being obtained for the most part by casting by the investment casting due to the poor machinability, formability and weldability. This casting method is quite laborious, and there is a risk of obtaining metallurgical defects as well. Besides, the the new technological process development and the production preparation require significant material and time costs. The authors proposed a post-processing technique with the high-current pulsed electron beams. RITM-SP integrated installation with low-energy high-current beams source and GEZA-MMP industrial installation with high-energy high-current electron beams source were employed for irradiation. The difference in surface modification by to the type of applied equipment was revealed. Namely, irradiation with a pulsed electron beam modifies a surface up to 8 microns thick with the RITM-SP installation, and over 44 microns when irradiated with the GEZA-MMP installation. Both surface and subsurface layers condition of the samples was studied by optical microscopy with a metallographic microscope. The article demonstrates that the pulsed electron beam effects significantly the labor intensity of parts machining and is a highly effective tool for surface modifying of the samples made by selective laser fusion from the CoCrMo alloy. The authors studied the interdependence of the electron beam processing modes and the positive dynamics of the important surface criteria changes (microhardness and roughness) of samples from the CoCrMo system alloy produced by additive technologies. The studies revealed that application of the pulsed electron beam processing reduces the surface roughness. While irradiating with GEZA-MMPabout 70% and with the RITM-SP about 40%, the authors managed to increase the micro-hardness by 20-25% as well. This fact is associated with the molybdenum content increase in the surface layer. The results of the conducted research substantiate the vector of further refinement of the technological process of electron beam processing of products and efforts on determining the operational properties of cobalt-chromium alloys, including fatigue trials and heat-resistant tests.
Keywords:
additive technologies, SLM technologies, post–processing, high-current pulsed electron beams, roughness, micro-hardnessReferences
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