Fabrication of a High Vanadium High Speed Steel by Liquid Phase Sintering

doi:10.11901/1005.3093.2015.729

Chinese Journal of Materials Research

2016, Vol. 30

Issue (9): 662-668 DOI: 10.11901/1005.3093.2015.729

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Fabrication of a High Vanadium High Speed Steel by Liquid Phase Sintering

Zhihua LI,Ping'an XIAO,Xia ZHANG,Ruiqing LU,Haibin LIU,Jinghong GU

School of Materials Science and Engineering, Hunan University, Changsha 410082, China

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Zhihua LI,Ping'an XIAO,Xia ZHANG,Ruiqing LU,Haibin LIU,Jinghong GU. Fabrication of a High Vanadium High Speed Steel by Liquid Phase Sintering. Chinese Journal of Materials Research, 2016, 30(9): 662-668.

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Abstract

High speed steels with high V content (HVHSS, 10 mass % of V) were fabricated by a process of pressing plus super solid-liquid phase sintering (SLPS) with atomized alloy powder as raw material. The effect of sintering parameters such as sintering temperature and holding time on densification, microstructure evolution as well as mechanical properties were systematically investigated, and the composition, morphology and distribution of the phases existed in the alloy were carefully analyzed. The results show that sintering temperature is the most important parameter affecting the performance of the sintered alloys, however holding time shows the main effect on the precipitation and evolution of carbides. The matrix of the as prepared HVHSS consists of acicular martensite and retained austensite, and there are three types of carbides, i.e. VC, complex molybdenum carbide and complex chromium carbide. Small spherical VC particles mainly distribute in the grains and along their boundaries. As sintering temperature and holding time increased, not only grains and carbides gradually coarsened but also more and more carbides precipitated. However, the precipitation of complex carbides deteriorates the alloy’s strength and toughness due to their poor morphology which cause serious stress concentration or forming carbide network along grain boundaries. The HVHSS possess high performance, such as hardness HRC 65-68, impact toughness and bending strength over 6 J/cm² and 1800 MPa respectively.

Key words: metallic materials HVHSS SLPS mechanical properties carbide

Received: 15 December 2015

Fund: *Supported by National Natural Science Foundation of China No.51574119

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	Zhihua LI
	Ping'an XIAO
	Xia ZHANG
	Ruiqing LU
	Haibin LIU
	Jinghong GU

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https://www.cjmr.org/EN/10.11901/1005.3093.2015.729 OR https://www.cjmr.org/EN/Y2016/V30/I9/662

Fig.1 Morphology of nitrogen atomized high vanadium cast iron powders

Fig.2 Effect of sintering temperature on density and hardness (holding time 2 h)

Fig.3 Effect of holding time on density and hardness (final sintering temperature 1245℃)

Fig.4 Effect of sintering temperature on microstructure (holding time 2 h) (a) 1235℃, (b) 1245℃, (c) 1255℃, (d) 1265℃, (e) 1275℃, (f) 1285℃, (g) 1295℃

Fig.5 XRD pattern of HVHSS with various sintering temperature

Fig.6 Effect of sintering temperature on grain size and carbide size

Fig.7 Effect of sintering holding time on microstructure (a) 30 min, (b) 60 min, (c) 90 min, (d) 120 min, (e) 150 min, (f) 180 min

Fig.8 Effect of sintering holding time on grain size and carbide size

Fig.9 Backscatter image of high vanadium steel prepared by powder metallurgy

Table 1 EDS analysis results of micro zone (atom fraction, %)

Fig.10 Effect of sintering temperature on impact toughness and bending strength

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