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Mechanical behavior and microstructure of low-carbon steel undergoing low-frequency vibration-assisted tensile deformation

Published online by Cambridge University Press:  20 September 2017

De’an Meng
Affiliation:
School of Mechanical Engineering, Xi’an Jiaotong University, Xi’an 710049, People’s Republic of China; and School of Engineering Technology, Purdue University, West Lafayette, Indiana 47906, USA
Xuzhe Zhao
Affiliation:
School of Engineering Technology, Purdue University, West Lafayette, Indiana 47906, USA
Jingxiang Li*
Affiliation:
School of Mechanical Engineering, Xi’an Jiaotong University, Xi’an 710049, People’s Republic of China; and Xi’an Jiaotong University Suzhou Academy, Suzhou, Jiangsu 215123, People’s Republic of China
Shengdun Zhao
Affiliation:
School of Mechanical Engineering, Xi’an Jiaotong University, Xi’an 710049, People’s Republic of China
Qingyou Han
Affiliation:
School of Engineering Technology, Purdue University, West Lafayette, Indiana 47906, USA
*
a) Address all correspondence to this author. e-mail: [email protected]
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Abstract

Ultrasonic vibration can lead to significant load reduction in metal forming, and this concept has been widely applied in microforming. Recently, we discovered that low-frequency mechanical vibration (less than 100 Hz) with micro-amplitudes also features the same effects. In this study, low-frequency vibration-assisted tensile deformation experiments were conducted on commercially low-carbon steel. Effects of vibration softening and residual softening were obtained during experiments. Both these softening effects became prominent at high vibration amplitudes. Detailed microstructural analyses reveal that a low-frequency vibration treatment altered the interior characteristics of the metal. Electron backscatter diffraction results showed low-angle grain boundaries, and the interior misorientation angle increased greatly with the application of a low-frequency vibration. Changes in the microstructure became more pronounced with the rise of vibration amplitudes. Instantaneous stress reduction results from the additional energy applied in the form of vibration, which lowers the barrier energy for the dislocation motion. The residual softening effect can be interpreted via a dislocation density decrease as a result of vibration markedly improving the opportunity for dislocation annihilation or stacking.

Type
Articles
Copyright
Copyright © Materials Research Society 2017 

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Footnotes

Contributing Editor: Jürgen Eckert

References

REFERENCES

Brehl, D. and Dow, T.: Review of vibration-assisted machining. Precis. Eng. 32, 153 (2008).Google Scholar
Han, Q.: Ultrasonic processing of materials. Metall. Mater. Trans. B 46, 1603 (2015).Google Scholar
Wang, C.J., Liu, Y., Guo, B., Shan, D.B., and Zhang, B.: Acoustic softening and stress superposition in ultrasonic vibration assisted uniaxial tension of copper foil: Experiments and modeling. Mater. Des. 112, 246 (2016).Google Scholar
Khosro Aghayani, M. and Niroumand, B.: Effects of ultrasonic treatment on microstructure and tensile strength of AZ91 magnesium alloy. J. Alloys Compd. 509, 114 (2011).Google Scholar
Bagherzadeh, S., Abrinia, K., Liu, Y., and Han, Q.: The effect of combining high-intensity ultrasonic vibration with ECAE process on the process parameters and mechanical properties and microstructure of aluminum 1050. Int. J. Adv. Manuf. Technol. 88, 229 (2016).Google Scholar
Kirchner, H., Kromp, W., Prinz, F., and Trimmel, P.: Plastic deformation under simultaneous cyclic and unidirectional loading at low and ultrasonic frequencies. Mater. Sci. Eng. 68, 197 (1985).Google Scholar
Rusinko, A.: Analytical description of ultrasonic hardening and softening. Ultrasonics 51, 709 (2011).Google Scholar
Hung, J-C. and Lin, C-C.: Investigations on the material property changes of ultrasonic-vibration assisted aluminum alloy upsetting. Mater. Des. 45, 412 (2013).Google Scholar
Daud, Y., Lucas, M., and Huang, Z.: Modelling the effects of superimposed ultrasonic vibrations on tension and compression tests of aluminium. J. Mater. Process. Technol. 186, 179 (2007).Google Scholar
Endo, T., Suzuki, K., and Ishikawa, M.: Effects of superimposed ultrasonic oscillatory stress on the deformation of Fe and Fe–3% Si alloy. Trans. Jpn. Inst. Met. 20, 706 (1979).Google Scholar
Liu, Y., Suslov, S., Han, Q., Hua, L., and Xu, C.: Comparison between ultrasonic vibration-assisted upsetting and conventional upsetting. Metall. Mater. Trans. A 44, 3232 (2013).Google Scholar
Osakada, K., Mori, K., Altan, T., and Groche, P.: Mechanical servo press technology for metal forming. CIRP Ann. 60, 651 (2011).Google Scholar
Matsumoto, R., Sawa, S., Utsunomiya, H., and Osakada, K.: Prevention of galling in forming of deep hole with retreat and advance pulse ram motion on servo press. CIRP Ann. 60, 315 (2011).Google Scholar
Li, C-H. and Tso, P-L.: Experimental study on a hybrid-driven servo press using iterative learning control. Int. J. Mach. Tool. Manuf. 48, 209 (2008).Google Scholar
Meng, D.a., Zhao, S., Li, L., and Liu, C.: A servo-motor driven active blank holder control system for deep drawing process. J. Adv. Des. Manuf. Technol. 87, 3185 (2016).Google Scholar
Maeno, T., Osakada, K., and Mori, K.: Reduction of friction in compression of plates by load pulsation. Int. J. Mach. Tool. Manuf. 51, 612 (2011).Google Scholar
Matsumoto, R., Jeon, J-Y., and Utsunomiya, H.: Shape accuracy in the forming of deep holes with retreat and advance pulse ram motion on a servo press. J. Mater. Process. Technol. 213, 770 (2013).Google Scholar
Groche, P. and Heß, B.: Friction control for accurate cold forged parts. CIRP Ann. 63, 285 (2014).Google Scholar
Wang, Z-h., Zhan, W-t., Hong, X-x., Bao, G-j., and Yang, Q-h.: Characteristics of metal flow in cold extrusion under electric-hydraulic chattering. J. Iron Steel Res. Int. 24, 138 (2017).Google Scholar
Kriechenbauer, S., Mauermann, R., and Muller, P.: Deep drawing with superimposed low-frequency vibrations on servo-screw presses. Precis. Eng. 81, 905 (2014).Google Scholar
Maeno, T., Mori, K., and Hori, A.: Application of load pulsation using servo press to plate forging of stainless steel parts. J. Mater. Process. Technol. 214, 1379 (2014).Google Scholar
Kumar, V. and Hutchings, I.: Reduction of the sliding friction of metals by the application of longitudinal or transverse ultrasonic vibration. Tribol. Int. 37, 833 (2004).Google Scholar
Meng, D.A., Zhao, S., and Zhu, C.: The effect of superimposed low-frequency vibration on tensile deformation of low-carbon steel. In 23rd International Congress on Sound & Vibration, Vogiatzis, K., Kouroussis, G., Crocker, M., and Pawelczyk, M., eds. (ICSV23, Athens, 2016); p. 723.Google Scholar
Yao, Z., Kim, G-Y., Faidley, L., Zou, Q., Mei, D., and Chen, Z.: Effects of superimposed high-frequency vibration on deformation of aluminum in micro/meso-scale upsetting. J. Mater. Process. Technol. 212, 640 (2012).Google Scholar
Siu, K.W., Ngan, A.H.W., and Jones, I.P.: New insight on acoustoplasticity—Ultrasonic irradiation enhances subgrain formation during deformation. Int. J. Plast. 27, 788 (2011).Google Scholar
Yao, Z., Kim, G-Y., Wang, Z., Faidley, L., Zou, Q., Mei, D., and Chen, Z.: Acoustic softening and residual hardening in aluminum: Modeling and experiments. Int. J. Plast. 39, 75 (2012).Google Scholar
Mecking, H. and Kocks, U.: Kinetics of flow and strain-hardening. Acta Metall. 29, 1865 (1981).Google Scholar
Siu, K.W. and Ngan, A.H.W.: Understanding acoustoplasticity through dislocations dynamics simulations. Philos. Mag. 91, 4367 (2011).Google Scholar