Characterization of Physical and Mechanical Properties of Tungsten Alloy Surfaces for Electroplasticity-Assisted Dry Cutting Machining

Tungsten alloy has a wide range of applications in aerospace and defense industry because of its high hardness, high strength and other excellent properties. Tungsten alloys are typical hard-to-machine materials, and the electroplastic effect can improve the machining surface quality of hard-to-mach...

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Published inInternational journal of precision engineering and manufacturing-green technology Vol. 11; no. 6; pp. 1745 - 1755
Main Authors Liu, Jie, Chen, Guangjun, Yu, Zhiwei, Jia, Xiongfei, Huang, Jiashuai
Format Journal Article
LanguageEnglish
Published Seoul Korean Society for Precision Engineering 01.11.2024
Springer Nature B.V
한국정밀공학회
Subjects
Defense industry
Deformation
Electric potential
Energy consumption
Energy Efficiency
Engineering
Frequency variation
High strength alloys
Industrial and Production Engineering
Lasers
Mechanical properties
Microhardness
Oxidation
Parameters
Physical properties
Regular Paper
Residual stress
Stainless steel
Steel alloys
Substrates
Surface layers
Surface properties
Sustainable Development
Thickness
Tungsten
Tungsten base alloys
Turning (machining)
Voltage
Work hardening
Workpieces
기계공학
Metamorphic layer
Electroplasticity-assisted dry turning
Work hardening
W93NiFe alloy
Residual stress
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Summary:Tungsten alloy has a wide range of applications in aerospace and defense industry because of its high hardness, high strength and other excellent properties. Tungsten alloys are typical hard-to-machine materials, and the electroplastic effect can improve the machining surface quality of hard-to-machine metal materials. However, the complex thermal–mechanical-electrical coupling generated by the relative motional squeezing of the tool and the workpiece under the electric pulse. It will cause a large difference between the physical and mechanical properties of the surface layer and the substrate material. The size and distribution of the characteristic parameters of the physical and mechanical properties of the machined surface, such as work hardening, residual stress and metamorphic layer, are not clear. Therefore, characterization of the physical and mechanical properties of the surface of W93NiFe alloy for electroplasticity-assisted dry turning machining was carried out in this paper. The results showed that the electrically plastic assisted dry turning process effectively alleviated the degree of work hardening on the machined surface of W93NiFe alloy. but the oxidation of the surface layer of the workpiece was exacerbated by excessive pulse voltage, which resulted in the increase of the surface microhardness again; Compared with conventional dry turning, the application of appropriate pulse voltage can effectively reduce the residual stress on the machined surface of W93NiFe alloy. and in this experiment, the variation of pulse frequency had less effect on the residual stress on the machined surface of W93NiFe alloy; After passing the pulse current, the thickness of the surface metamorphic layer increased significantly with the increase of electrical parameters such as pulse voltage and pulse frequency. but there was no significant effect of the two processing methods on the internal organization of W93NiFe alloy.
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https://link.springer.com/article/10.1007/s40684-024-00619-7
ISSN:2288-6206
2198-0810
DOI:10.1007/s40684-024-00619-7