Effect of Heat Treatment on Microstructure and Mechanical Properties of Quenching and Partitioning Steel

doi:10.1007/s40195-017-0667-3

Abstract

Abstract:

In order to investigate the effect of microstructural characterization on the mechanical properties and retained austenite stability, a different type of quenching and partitioning steel (I-Q&P) through intercritical annealing before the quenching and partitioning process was designed, which can realize lamellar intercritical microstructure compared to the conventional quenching and partitioning (Q&P) process. The morphology of ferrite and martensite/retained austenite is lamellar in the I-Q&P steel while it is equiaxed after being heat-treated by conventional Q&P process. The I-Q&P steel is proved to have better formability and mechanical properties than conventional Q&P steel, which is due to the higher-volume fraction of retained austenite in the I-Q&P steel and confirmed by electron backscattering diffraction patterns and X-ray diffraction. Furthermore, the stability of retained austenite in I-Q&P steel is also higher than that in conventional Q&P steel, which is investigated by tensile tests and differential scanning calorimetry.

Key words: Quenching and partitioning steel, Heat treatment, Retained austenite, Stability, Activation energy

Shao-Heng Sun, Ai-Min Zhao, Ran Ding, Xiao-Gang Li. Effect of Heat Treatment on Microstructure and Mechanical Properties of Quenching and Partitioning Steel[J]. Acta Metallurgica Sinica (English Letters), 2018, 31(2): 216-224.

Figures/Tables 16

Table 1 Chemical composition of Q&P steel (wt%)

C	Si	Mn	P	S	Al	Nb
0.23	1.93	2.18	0.0081	0.0044	0.043	0.023

Fig. 1 Schematic diagram of heat treatments for conventional a and I-Q&P b samples. OQ oil-quenching, RT room temperature

Fig. 2 Microstructure of tested steel before Q&P process (PAGB: prior austenite grain boundary): a conventional sample; b I-Q&P sample

Fig. 3 SEM micrographs of conventional a and I-Q&P b samples (PAGB, TM, UM, AM, RA, ARA, and F refer to prior austenite grain boundary, tempered martensite, untempered martensite, acicular martensite, retained austenite, acicular-retained austenite, and ferrite, respectively)

Table 2 Volume fraction of each constituent phase and mass fraction of carbon in retained austenite of tested steels

Sample	f _F (%)	f _TM (%)	f _UM (%)	f _RA (%)	C _γ (%)
Conventional	57.53	22.47	14.23	5.77	1.097
I-Q&P	41.42	38.58	6.03	13.97	1.070

Fig. 4 EBSD images of conventional a and I-Q&P b samples with the color region representing retained austenite

Fig. 5 Volume fraction of retained austenitic as a function of tensile deformation for tested steels

Fig. 6 Variations of k values as a function of true strain in tested steels

Fig. 7 Dilatometry curves for conventional a and I-Q&P b samples after different heat treatments

Fig. 8 Heat flow of tested steels as a function of temperature at heating rates of 5 K/min a, 10 K/min b, 15 K/min c, 20 K/min d

Fig. 9 Kissinger analysis (ln (T 2 /Θ) vs. 1/T) for determination of activation energy of retained austenite decomposition

Fig. 10 Engineering stress-strain curves of tested steels

Table 3 Mechanical properties of tested steels after Q&P treatment

Sample	R _0.2 (MPa)	R _m (MPa)	YR	A (%)	R _m × A (GPa%)
Conventional	517.99	1197.61	0.4325	9.5	11.77295
I-Q&P	541.98	1112.83	0.4870	28.0	31.15924

Fig. 11 Cupping force-travel curves and photos of conventional a and I-Q&P b samples after Erichsen testing

Fig. 12 Instantaneous work-hardening exponent n for conventional and I-Q&P samples as a function of true strain

Fig. 13 SEM micrographs of fracture surfaces of conventional a and I-Q&P b samples

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