Effects of niobium addition on microstructure and properties of CPM121 powder metallurgy high-speed steel

Qian-kun Zhang; Su-wang Li; Yi-feng Xiao; Liang Wu; Jin-wen Qian; Ze-min Chen; Wei-jun Shen; Nan Lin; Yue-hui He

doi:10.1007/s11771-021-4690-1

Journal of Central South University ›› 2021, Vol. 28 ›› Issue (4) : 1206 -1218. DOI: 10.1007/s11771-021-4690-1

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Effects of niobium addition on microstructure and properties of CPM121 powder metallurgy high-speed steel

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Abstract

Massive vanadium additions as hard phases in powder metallurgy high-speed steels (PM HSS) lead to higher cost and bad machinability. In this study, ultrahigh alloy PM HSS with CPM121 (10W−5Mo−4Cr−10V−9Co, wt.%) as the basic composition, was directly compacted and activation sintered with near-full density (>99.0%) using pre-oxidized and ball-mixed element and carbide powders. Niobium-alloyed steels (w(V)+w(Nb)=10 wt.%) show higher hardness and wear resistance, superior secondary-hardening ability and temper resistance. But excess niobium addition (>5 wt.%) leads to coarsened carbides and deteriorated toughness. EPMA results proved that niobium tends to distribute in MC carbides and forces element W to form M₆C and WC carbides. Further, the role of rotary forging on properties of niobium-alloyed steels (S3) was researched. After rotary forging with deformation of 40%, the bending strength and fracture toughness of niobium-alloyed steels could be further improved by 20.74% and 43.86% compared with those of sample S3 without rotary forging, respectively.

Keywords

CPM121 / niobium-alloying / microstructure / mechanical properties / temper resistance / wear resistance / rotary forging / powder metallurgy

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Qian-kun Zhang, Su-wang Li, Yi-feng Xiao, Liang Wu, Jin-wen Qian, Ze-min Chen, Wei-jun Shen, Nan Lin, Yue-hui He. Effects of niobium addition on microstructure and properties of CPM121 powder metallurgy high-speed steel. Journal of Central South University, 2021, 28(4): 1206-1218 DOI:10.1007/s11771-021-4690-1

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