Effects of Magnetic Field on the Residual Stress and Structural Defects of Ti-6Al-4V

Zhang, Xu; Zhao, Qi; Cai, Zhipeng; Pan, Jiluan

doi:10.3390/met10010141

Cited by 23 publications

(17 citation statements)

References 32 publications

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“…The result is that the covalent bond is much easier to break. The atomic mobility is enhanced and the atom-migration-related processes are prompted [34]. Thus, the mobility of vacancy or impurity atoms increases so that the dislocation depinning could occur under the original stress field and leads to the dislocation movement.…”

Section: Mechanism Of Dislocation Movement With Magnetic Treatmentmentioning

confidence: 99%

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Effects of Pulsed Magnetic Fields of Different Intensities on Dislocation Density, Residual Stress, and Hardness of Cr4Mo4V Steel

Hou

et al. 2020

Crystals

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To study the effects of pulsed magnetic fields of different intensities on the dislocation density, residual stress, and hardness of Cr4Mo4V steel, magnetic treatment is conducted at 0, 1.0, 1.3, 1.5, 2.0, and 2.5 T. The dislocation density and residual stress are measured using Electron Backscatter Diffraction (EBSD) and X-ray technique, respectively. The results reveal the dislocation density and compressive residual stress decrease at lower magnetic fields such as 1.0 T and 1.3 T, while they increase at higher magnetic fields such as 2.0 T and 2.5 T. The average value of kernel averaged misorientation (KAM) and compressive residual stress decrease about 10.4% and 15.8%, respectively, at 1.0 T, while they increase about 5.88% and 18.2%, respectively, at 2.5 T. The average value of hardness decreases about 3.5% at 1.0 T, from 817 HV to 787 HV. With the increments of intensities, the hardness of the treated samples increases. The hardness essentially remains unchanged at 2.0 T and 2.5 T. The reason for the dislocation motion under the action of pulsed magnetic fields is discussed.

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Section: Mechanism Of Dislocation Movement With Magnetic Treatmentmentioning

confidence: 99%

“…This vibration provides energy for the dislocation movement. It should be emphasized that the thermal energy induced by a magnetic field with an intensity of several Teslas is ignorable [34]. As the total processing time is only 55 s, the temperature of the Cr4Mo4V steel sample hardly changes.…”

Section: Mechanism Of Dislocation Movement With Magnetic Treatmentmentioning

confidence: 99%

Effects of Pulsed Magnetic Fields of Different Intensities on Dislocation Density, Residual Stress, and Hardness of Cr4Mo4V Steel

Hou

et al. 2020

Crystals

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“…We note that the peak values of the EPR spectra increased by 7.28% at the signal crest and 29% at the signal trough after EMCFP treatment. Magnetic eld can increase the number of unpaired electrons which can change the state of free radical form (Singlet) S to (Triplet) T [7,19]. The combine energy of electron pair is strong in S state, but weak in T state.…”

Section: In Uence Of Emcfp On the Erp Spectra Of Cutting Toolsmentioning

confidence: 99%

“…Under the combined impacts of the electro-plastic effect [21,22] and the magnetostriction effect [23], the EMCFP treatment increased dislocation mobility by decreasing the activation energy of dislocation movement, which promoted internal stress release. In addition, the EMCFP process provides the necessary energy for dislocation motions to occur, resulting in the homogenization of the dislocation distribution in the material [7]. Simultaneously, applied electric elds reduce entanglement between dislocations, which removes obstacles toward dislocation slippage, so that the material exhibits higher plasticity [24].…”

Section: In Uence Of Emcfp On the Erp Spectra Of Cutting Toolsmentioning

confidence: 99%

“…The results indicated that the optimum magnetic eld enhanced coating properties, resulting in a reduced friction coe cient and increased wear resistance. Zhang et al [7] applied a magnetic eld during the processing of a titanium alloy, and the tensile stress was observed to be decreased by 24% owing to the homogenization of the residual stress via the excitation of dislocation relaxations by the magnetic eld. Xu et al [8] investigated the in uence of pulsed magnetic eld treatment on the microstructure of TC4 titanium alloy.…”

Section: Introductionmentioning

confidence: 99%

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Effect of P10 Cemented Carbide Cutting Tools Subjected to Electromagnetic Coupling Field Treatment on the Surface Roughness of Machined 45 Steel

Zhong

Yuan

Meng

et al. 2021

Preprint

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Reducing the surface roughness of machined workpieces is of great interest owing to its potential for improving the quality of finished items and decreasing the cost of machining processes by reducing the need for post processing. This paper contributes to this research by analyzing the effect of P10 cemented carbide cutting tools subjected to pulsed electromagnetic coupling field processing (EMCFP) treatment on the surface roughness of machined 45 steel workpieces. The effects of untreated and EMCFP-treated cutting tools on workpiece surface roughness, tool lifetime, friction coefficient, electron paramagnetic resonance (EPR) spectra, dislocation density and residual stress are compared. The experimental results demonstrate that EMCFP treatment can reduce the average surface roughness of workpieces by 39.2%, enhance tool lifetime by a factor of 1.92, reduce the friction coefficient by 11.4%, increase the intensities of peak EPR signals, increase the dislocation density by 38% and decrease the residual stress of the tool flank face by 51.4% . This research provides scientific data and technical support for EMCFP technology with important scientific significance.

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Residual stress reductions of carbide cutting tools through applying pulsed magnetic field and coupled electromagnetic field – mechanism analysis and comparison study

Zhong

Wang

Zhang

et al. 2022

Int J Adv Manuf Technol

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Effects of Magnetic Field on the Residual Stress and Structural Defects of Ti-6Al-4V

Cited by 23 publications

References 32 publications

Effects of Pulsed Magnetic Fields of Different Intensities on Dislocation Density, Residual Stress, and Hardness of Cr4Mo4V Steel

Effects of Pulsed Magnetic Fields of Different Intensities on Dislocation Density, Residual Stress, and Hardness of Cr4Mo4V Steel

Effect of P10 Cemented Carbide Cutting Tools Subjected to Electromagnetic Coupling Field Treatment on the Surface Roughness of Machined 45 Steel

Residual stress reductions of carbide cutting tools through applying pulsed magnetic field and coupled electromagnetic field – mechanism analysis and comparison study

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