Application of High-Density Electropulsing to Improve the Performance of Metallic Materials: Mechanisms, Microstructure and Properties

Sheng, Yuqi; Hua, Youlu; Wang, Xiaojian; Zhao, Xueyang; Chen, Lianxi; Zhou, Hanyu; Wang, James; Berndt, C. C.; Li, Wei

doi:10.3390/ma11020185

Cited by 74 publications

(24 citation statements)

References 146 publications

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“…Previous studies [25,26] have indicated that heavily cold worked metals could be subdivided by grain boundaries and dislocation boundaries. The cold work inducing the formation of the grain boundary was also found in CR AZ91 alloy [27] and 308L stainless steel [28]. In this 316LN ASS, in addition to dislocation grain boundaries, the boundaries of mechanical twins and strain-induced martensite formed during the CR process can also subdivide untransformed austenite, leading to the decrease of the untransformed austenite structure size.…”

Section: The Effect Of Cold Deformation On the Microstructuresmentioning

confidence: 73%

Effect of Cold Deformation on Microstructures and Mechanical Properties of Austenitic Stainless Steel

Wan

et al. 2018

Metals

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In this paper, the effect of cold deformation on the microstructures and mechanical properties of 316LN austenitic stainless steel (ASS) was investigated. The results indicated that the content of martensite increased as the cold rolling reduction also increased. Meanwhile, the density of the grain boundary in the untransformed austenite structure of CR samples increased as the cold reduction increased from 10% to 40%, leading to a decreased size of the untransformed austenite structure. These two factors contribute to the improvement of strength and the decrease of ductility. High yield strengths (780-968 MPa) with reasonable elongations (30.8-27.4%) were achieved through 20-30% cold rolling. The 10-30% cold-rolled (CR) samples with good ductility had a good strain hardening ability, exhibiting a three-stage strain hardening behavior.

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Section: The Effect Of Cold Deformation On the Microstructuresmentioning

confidence: 73%

Effect of Cold Deformation on Microstructures and Mechanical Properties of Austenitic Stainless Steel

Wan

et al. 2018

Metals

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“…In addition, due to the repulsion effect, the distance between inclusions (e.g., the inclusions M and N in Figure b) is greater than that of the untreated sample (Figure a). In fact, the electric current affects many other second phases whose conductivity are different from that of matrix . Electric current causes the fragment of lamellar cementite to be perpendicular to current .…”

Section: Resultsmentioning

confidence: 99%

Achieving the Control of Nonmetallic Inclusions Morphology and Orientation by Electric Current

Liu

Zhang

2019

steel research int.

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The evolution of inclusions in electric field is investigated using numerical calculations. Due to electric current bypassing the inclusions, the electric current streamlines are not uniformly distributed but concentrated and distorted around inclusions. This abnormal electric current distribution causes an interaction force of adjacent inclusions, which is determined by the distance and orientation of the inclusions. The interaction force has three effects on the inclusions, i.e., attraction, repulsion, and rotation. The influence of three effects on the morphology, orientation, and distribution of inclusions is discussed. As a result, the inclusions evolve into a chain‐like structure aligned with the current direction, and inclusions separate from each other causing dispersion in the perpendicular direction. The evolution of the inclusions obeys the rule that the improvement of material conductivity reduces the electric free energy. The numerical calculation results are consistent with the experimental phenomena.

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“…hence, a change in the residual stresses of the single phase was expected [30,[50][51][52][53]. An increase in compression stress amounts in ferrite after the first electropulsing treatment was determined and this did not change even after the electropulsing treatment at higher current density and higher number of pulses (Figure 16a).…”

Section: Residual Stressesmentioning

confidence: 87%

“…Since tensile test introduces uniaxial stress configuration in the specimen, no variation in the average residual internal stresses was expected. On the other hand, electropulsing treatments have shown to induce changes in the grain orientation within the materials not to mention the change in morphology of secondary low conductivity phases (i.e., cementite particles in perlite) hence, a change in the residual stresses of the single phase was expected [30,[50][51][52][53]. An increase in compression stress amounts in ferrite after the first electropulsing treatment was determined and this did not change even after the electropulsing treatment at higher current density and higher number of pulses (Figure 16a).…”

Section: Residual Stressesmentioning

confidence: 99%

Influence of Electropulsing Treatments on Mechanical Properties of UNS S32750 Duplex Stainless Steel

et al. 2020

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Prestrained at 5% and 15% duplex stainless steel UNS S32750 specimens have been subjected to electropulsing treatments with current density of 100 A/mm2 and 200 A/mm2 and 100 and 500 pulses for each current density value. Corrosion tests, X-ray diffraction, microhardness and residual stresses were collected before and after the electropulsing treatments. Tensile tests were performed after the electropulsing treatments in order to compare the mechanical response to reference tensile tests performed before pulsing treatments. Increase in fracture strain was observed after pulsing treatment in comparison to the reference tensile tests. A decrease in microhardness was also observed after electropulsing treatments for both degrees of prestrain. Electropulsing treatment almost eliminates the work-hardened state in the 5% prestrained specimens while partially recovered the 15% prestrained material increasing both uniform and fracture strain. Bulk temperature of the samples remained the same for all treatments duration. The effect are to be addressed to a combined effect of increase in atomic flux due to the electrical current and local joule heating in correspondence of crystal defects. Electropulsing treatment applied to metallic alloys is a promising technique to reduce the work hardening state without the need of annealing treatments in a dedicated furnace.

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Application of High-Density Electropulsing to Improve the Performance of Metallic Materials: Mechanisms, Microstructure and Properties

Cited by 74 publications

References 146 publications

Effect of Cold Deformation on Microstructures and Mechanical Properties of Austenitic Stainless Steel

Effect of Cold Deformation on Microstructures and Mechanical Properties of Austenitic Stainless Steel

Achieving the Control of Nonmetallic Inclusions Morphology and Orientation by Electric Current

Influence of Electropulsing Treatments on Mechanical Properties of UNS S32750 Duplex Stainless Steel

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