Carbide dissolution and precipitation in cold-rolled type 347H austenitic heat-resistant steel

Yanmo Li; Yongchang Liu; Chenxi Liu; Chong Li; Yuan Huang; Huijun Li; Wenya Li

doi:10.1016/j.matlet.2016.11.081

Carbide dissolution and precipitation in cold-rolled type 347H austenitic heat-resistant steel

Yanmo Li, Yongchang Liu, Chenxi Liu, Chong Li, Yuan Huang, Huijun Li, Wenya Li

School of Materials Sience and Engineering

Tianjin University

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

Cold-rolled (CR) type 347H austenitic heat-resistant steel is investigated in this study, and the main strengthening phase, NbC, experiences the procedures of dissolution and precipitation twice, with the increase of deformation degree from 30% to 90%. Most of the primary NbC particles, remained during the solution treatment, dissolve in the austenitic matrix when the deformation degree is 30%, and rod-like NbC generates along the prior austenite grain boundary. Further deformation leads to the fragmentation and decomposition of the rod-like NbC. Until the cold rolling reduction reaches 90%, the dissolved NbC secondarily precipitates into nanoparticles and disperses throughout the martensite induced by deformation. The tensile strength of the 90% cold-deformed specimen, 1418 MPa, is enhanced by three times in contrast with the undeformed one.

Original language	English
Pages (from-to)	70-73
Number of pages	4
Journal	Materials Letters
Volume	189
DOIs	https://doi.org/10.1016/j.matlet.2016.11.081
State	Published - 15 Feb 2017

Keywords

Carbide dissolution
Carbide precipitation
Cold rolling
Metals and alloys
Microstructure

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10.1016/j.matlet.2016.11.081

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title = "Carbide dissolution and precipitation in cold-rolled type 347H austenitic heat-resistant steel",

abstract = "Cold-rolled (CR) type 347H austenitic heat-resistant steel is investigated in this study, and the main strengthening phase, NbC, experiences the procedures of dissolution and precipitation twice, with the increase of deformation degree from 30% to 90%. Most of the primary NbC particles, remained during the solution treatment, dissolve in the austenitic matrix when the deformation degree is 30%, and rod-like NbC generates along the prior austenite grain boundary. Further deformation leads to the fragmentation and decomposition of the rod-like NbC. Until the cold rolling reduction reaches 90%, the dissolved NbC secondarily precipitates into nanoparticles and disperses throughout the martensite induced by deformation. The tensile strength of the 90% cold-deformed specimen, 1418 MPa, is enhanced by three times in contrast with the undeformed one.",

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author = "Yanmo Li and Yongchang Liu and Chenxi Liu and Chong Li and Yuan Huang and Huijun Li and Wenya Li",

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T1 - Carbide dissolution and precipitation in cold-rolled type 347H austenitic heat-resistant steel

AU - Li, Yanmo

AU - Liu, Yongchang

AU - Liu, Chenxi

AU - Li, Chong

AU - Huang, Yuan

AU - Li, Huijun

AU - Li, Wenya

PY - 2017/2/15

Y1 - 2017/2/15

N2 - Cold-rolled (CR) type 347H austenitic heat-resistant steel is investigated in this study, and the main strengthening phase, NbC, experiences the procedures of dissolution and precipitation twice, with the increase of deformation degree from 30% to 90%. Most of the primary NbC particles, remained during the solution treatment, dissolve in the austenitic matrix when the deformation degree is 30%, and rod-like NbC generates along the prior austenite grain boundary. Further deformation leads to the fragmentation and decomposition of the rod-like NbC. Until the cold rolling reduction reaches 90%, the dissolved NbC secondarily precipitates into nanoparticles and disperses throughout the martensite induced by deformation. The tensile strength of the 90% cold-deformed specimen, 1418 MPa, is enhanced by three times in contrast with the undeformed one.

AB - Cold-rolled (CR) type 347H austenitic heat-resistant steel is investigated in this study, and the main strengthening phase, NbC, experiences the procedures of dissolution and precipitation twice, with the increase of deformation degree from 30% to 90%. Most of the primary NbC particles, remained during the solution treatment, dissolve in the austenitic matrix when the deformation degree is 30%, and rod-like NbC generates along the prior austenite grain boundary. Further deformation leads to the fragmentation and decomposition of the rod-like NbC. Until the cold rolling reduction reaches 90%, the dissolved NbC secondarily precipitates into nanoparticles and disperses throughout the martensite induced by deformation. The tensile strength of the 90% cold-deformed specimen, 1418 MPa, is enhanced by three times in contrast with the undeformed one.

KW - Carbide dissolution

KW - Carbide precipitation

KW - Cold rolling

KW - Metals and alloys

KW - Microstructure

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U2 - 10.1016/j.matlet.2016.11.081

DO - 10.1016/j.matlet.2016.11.081

M3 - 文章

AN - SCOPUS:84999015143

SN - 0167-577X

VL - 189

SP - 70

EP - 73

JO - Materials Letters

JF - Materials Letters

ER -

Carbide dissolution and precipitation in cold-rolled type 347H austenitic heat-resistant steel

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Keywords

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