Residual Stress Removal Under Pulsed Electric Current

doi:10.1007/s40195-019-00941-z

摘要/Abstract

Abstract:

The effect of a pulsed electric current on the residual stress evolution of metal materials has been investigated. It was found that the surface and internal residual stresses in the as-quenched samples were reduced dramatically by electropulsing. A large number of experimental data show that the residual stress reduction is proportional to the initial residual stress and related to the material properties and electropulsing parameters. Under the combined actions of drift electrons, Joule heating, and residual stress, the dislocation mobility was enhanced, resulting in plastic strain and the decrease in residual stress. Drift electrons played a unique role in the electropulsing treatment, acting as an additional force pushing dislocations forward. The dislocations ultimately accumulated at a grain boundary, forming a parallel arrangement. Finally, the phenomenological equation of the residual stress evolution under electropulsing was derived from the experimental data.

Key words: Electroplastic, Residual stress, Dislocation movement, Phenomenological equation

. [J]. Acta Metallurgica Sinica (English Letters), 2020, 33(2): 281-289.

Siqi Xiang, Xinfang Zhang. Residual Stress Removal Under Pulsed Electric Current[J]. Acta Metallurgica Sinica (English Letters), 2020, 33(2): 281-289.

图/表 8

Fig. 1 Typical profiles of current density versus time for electropulses produced by capacitors connected in series and in parallel

Fig. 2 Surface residual stress of approximately 70 as-quenched samples before and after electropulsing treatment at different current densities: a 3942 A/mm2, b 4482 A/mm2, c 5184 A/mm2, d 5562 A/mm2. Square and circular points with the same serial number correspond to the same sample before and after electropulsing treatment, respectively

Fig. 3 Residual stresses of the as-quenched sample and electropulsed samples at different depths

Fig. 4 Residual stress reduction in the samples with initial residual stresses ranging from 50 to 500 MPa after electropulsing treatment at different current densities: a 3942 A/mm2, b 4482 A/mm2, c 5184 A/mm2, d 5562 A/mm2

Fig. 5 Residual stress reduction rate versus current density

Fig. 6 Plastic strain \(\Delta \varepsilon_{\text{p}}\) versus current density. The solid line is the experimentally obtained relationship between the plastic strain and the current density of six groups of samples, where the initial residual stress of the samples in each group was the same. The dashed lines are the experimental results of Conrad [13]

Fig. 7 TEM images of a as-quenched sample, b sample treated by electropulsing at a current density of 5184 A/mm2. These samples were observed from the [110] direction

Fig. 8 Determination of dislocation line directions. a Image obtained in the [001] beam direction. The dislocation lines are 65° from the horizontal. b Image obtained in the [023] beam direction. The dislocation lines are 58° from the horizontal. The samples were treated by electropulsing at a current density of 5184 A/mm2

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