Effect of High-Energy and Instantaneous Electropulsing Treatment on Microstructure and Propertiesof 42CrMo Steel

doi:10.11900/0412.1961.2017.00562

Acta Metall Sin

2018, Vol. 54

Issue (9): 1245-1252 DOI: 10.11900/0412.1961.2017.00562

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Effect of High-Energy and Instantaneous Electropulsing Treatment on Microstructure and Propertiesof 42CrMo Steel

Dong PAN, Yuguang ZHAO, Xiaofeng XU(

), Yitong WANG, Wenqiang JIANG, Hong JU

Key Laboratory of Automobile Materials, Ministry of Education, Department of Materials Science and Engineering, Jilin University, Changchun 130025, China

Cite this article:

Dong PAN, Yuguang ZHAO, Xiaofeng XU, Yitong WANG, Wenqiang JIANG, Hong JU. Effect of High-Energy and Instantaneous Electropulsing Treatment on Microstructure and Propertiesof 42CrMo Steel. Acta Metall Sin, 2018, 54(9): 1245-1252.

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Abstract

42CrMo steel was widely used in many industry fields for its excellent hardenability and high temperature strength. Many transmission mechanisms and fasteners, such as roller and heat-resistant gear, are made of this steel. However, the ductility of 42CrMo steel is relatively low after quenching and tempering. During high tempering Mo riched carbides at grain boundary and undecomposable martensite at low tempering are the main reasons for poor ductility of 42CrMo steel. Grain refinement can enhance both strength and ductility significantly, but traditional refinement technology will cause intergranular oxidation so that strengthening effect was weak. Although thermomechanical treatment can achieve dynamic recrystallization, its refinement effect is unstable. Elecropulsing treatment, which makes significant change in microstructure and properties of metals, has been applied in many fields such as, modification of solidified microstructure of liquid metal, healing of fatigue crack, nanocrystallization of amorphous materials and so on. Moreover, this process can produce superior mechanical properties in metals. In order to improve the mechanical properties of 42CrMo steel better, high-energy and instantaneous electropulsing treatment was applied. In this contribution, 42CrMo steel was subjected to traditional and electropulsing treatment individually. It was found that EPQ treatment (480 ms electropulsing treatment, water cooled) results in finer grain, promoting the formation of retained austenite and twin martensite; EPT treatment (180 ms electropulsing treatment, air cooled) can stabilize retained austenite in EPQ specimen and induce multiphase structure. Mechanical properties results indicate that strength-ductility balance of EPQ and EPQ+EPT specimen are 32% and 13.9% higher than that of TQ (traditional quenched) and EPQ+TT (traditional tempered) specimen respectively.

Key words: electropulsing treatment 42CrMo steel multiphase microstructure retained austenite strength-ductility balance

Received: 29 December 2017

ZTFLH:

TG142.1

Fund: Supported by National Natural Science Foundation of China (No.51701080)

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	Dong PAN
	Yuguang ZHAO
	Xiaofeng XU
	Yitong WANG
	Wenqiang JIANG
	Hong JU

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https://www.ams.org.cn/EN/10.11900/0412.1961.2017.00562 OR https://www.ams.org.cn/EN/Y2018/V54/I9/1245

Fig.1 Process diagram (a) and schematic of electro-pulsing equipment (b) (EPQ—electropulsing treatment with water-cooling (WC), TQ—traditional quenching, EPT—electropulsing treatment with air-cooling (AC), TT—traditional tempering)

Fig.2 OM images of initial (a), TQ (b) and EPQ (c) samples

Fig.3 Microstructures (insets) and distribution statistics of prior austenite grain of TQ (a) and EPQ (b) samples

Fig.4 TEM images (a, c, e) and SAED patterns (b, d, f) of lath martensite in TQ samples (a, b), twin martensite (c, d) and retained austenite films (e, f) in EPQ samples (M—martensite, T—twin, RA—retained austenite)

Fig.5 XRD spectra of quenched and tempered samples

Fig.6 SEM images of EPQ+EPT (a) and EPQ+TT (b) samples (TM—tempered martensite, S—sorbite)

Fig.7 Tensile curves (a), normalized work-hardening rates of quenched samples (b) and tempered samples (c) (ε—true strain)

Table 1 Mechanical properties of initial, quenched and tempered samples

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