Study on three--body impact--abrasion of steel treated by quenching--partitioning--tempering process

Chin J Mater Res

2009, Vol. 23

Issue (3): 305-310 DOI:

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Study on three--body impact--abrasion of steel treated by quenching--partitioning--tempering process

WANG Cunyu ¹; SHI Jie ¹; LIU Su ¹; DU Shaofeng ¹; DONG Han¹

1.Institute for Structural Materials; Central Iron $\&$ Steel Research Institute; Beijing 100081
2.Center of Technology; Inner Mongolia First Machinery Group; Baotou 014032

Cite this article:

WANG Cunyu SHI Jie LIU Su DU Shaofeng DONG Han. Study on three--body impact--abrasion of steel treated by quenching--partitioning--tempering process. Chin J Mater Res, 2009, 23(3): 305-310.

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Abstract

The effect of “quenching--partitioning--tempering”(Q--P--T) process on three--body impact--abrasion of 20Si2Ni3 steel was investigated. The results show that as increasing of the impact energy from 0.5 J to 3.5 J, the mass loss of the samples increases firstly and then decreases, and reaches maximum value at the impact energy of 2.5 J. The mass loss of the samples treated by Q--P--T is lower than those treated by Q--T. Major abrasion behavior is transition from cut to fatigue, and the thickness of the surface work--hardening for the samples treated by Q--P--T is much larger than that of Q--T treated. It is reasonable to propose that the better resistance in impact abrasive for the samples treated by Q--P--T process arises from high--toughness, work--hardening of the alloy matrix, the phase and deformation transformation strengthening of the retained austenite
during abrasing.

Key words: metallic materials, martensite quenching--partitioning--tempering process three body impact abrasive wear retained austenite

Received: 18 December 2008

ZTFLH:

TG115

Fund:

Supported by National High--Tech Research and Development Program No.2009AA03Z519.

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