Method of shape and property control of electric arc additive manufacturing through assistance of ultrasonic vibration

Abstract

The invention discloses a method of shape and property control of electric arc additive manufacturing through assistance of ultrasonic vibration. In the process of electric arc additive manufacturing, non-contact ultrasonic vibration is applied to molten baths synchronously, grains in the molten baths are crushed, growth of the grains is restrained, and refinement of the grains is achieved. Meanwhile, by effectively utilizing residual heat of a formed part, the effect that a material in the position where a tool bit makes contact with the surface of a cladding layer is in a softened state is guaranteed, by applying ultrasonic vibration to the tool bit, the tool bit impacts the surface of the cladding layer at a high frequency, and finishing processing and surface reinforcing treatment are conducted on the surface, so that the dimension precision of the cladding layer is improved, the residual stress of the cladding layer is reduced, the surface grains are refined, and accordingly the purpose of shape and property control of electric arc additive manufacturing is achieved. According to the method, the roughening effect of the residual heat accumulation amount to the part grains and severe influences of warping deformation are reduced and even avoided, the service cycle of the tool bit is prolonged, and subsequent machining treatment of parts is reduced. The effective method is provided for shape and property control of the electric arc additive manufacturing technology.

Description

Technical field [0001] The invention belongs to the technical field of additive manufacturing, and specifically relates to a method for controlling the shape and control of ultrasonic vibration-assisted arc additive manufacturing. Background technique [0002] Additive manufacturing technology is based on the principle of discrete-stacking, with the aid of a computer, by means of wire feeding or powder spreading, using high-energy beams (laser, electron beam, plasma, arc) as the heat source to deposit molten raw materials layer by layer Accumulation realizes mold-free and rapid prototyping of parts. Compared with the additive manufacturing technology based on laser, plasma beam, and electron beam as the heat source, the arc additive manufacturing technology has the advantages of low production cost, high deposition efficiency, and unlimited size of formed parts. It is especially suitable for manufacturing aerospace fields. Manufacturing of integrated components such as medium an...

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Problems solved by technology

For example, Professor Zhang Haiou of Huazhong University of Science and Technology (see Zhang Haiou, Xiong Xinhong, Wang Guilan, etc. Plasma deposition forming and milling finishing combined direct manufacturing metal parts technology [J]. China Mechanical Engineering, 2005, 16(20): 1863-1866 .) Combining additive manufacturing and milling process to solve the precision problem of additive manufacturing formed parts, in the deposition-milling composite process, usually when one or several layers are deposited, the surface of the deposition layer is milled flat, and then The deposition of the next layer is carried out. This process effectively solves the problem of surface unevenness in the height and width directions of the deposition layer, avoids the influence of the surface morphology of the previous deposition layer on the subsequent deposition layer, and improves the forming process. However, this process cannot effectively reduce or even eliminate the residual stress of each cladding layer, as well as the ef

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