节约型双相不锈钢<strong>TRIP</strong>效应致塑性增量及其固溶温度依赖性

doi:10.11900/0412.1961.2019.00108

金属学报

2019, Vol. 55

Issue (11): 1359-1366 DOI: 10.11900/0412.1961.2019.00108

研究论文

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节约型双相不锈钢TRIP效应致塑性增量及其固溶温度依赖性

陈雷^1,²,郝硕^1,²,梅瑞雪²,贾伟²,李文权²,郭宝峰²(

)

1. 燕山大学国家冷轧板带装备及工艺工程技术研究中心秦皇岛 066004
2. 燕山大学机械工程学院秦皇岛 066004

Intrinsic Increment of Plasticity Induced by TRIP and Its Dependence on the Annealing Temperature in a Lean Duplex Stainless Steel

CHEN Lei^1,²,HAO Shuo ^1,²,MEI Ruixue ²,JIA Wei ²,LI Wenquan ²,GUO Baofeng²(

)

1. National Engineering Research Center for Equipment and Technology of Cold Strip Rolling, Yanshan University, Qinhuangdao 066004, China
2. College of Mechanical Engineering, Yanshan University, Qinhuangdao 066004, China

引用本文:

陈雷, 郝硕, 梅瑞雪, 贾伟, 李文权, 郭宝峰. 节约型双相不锈钢TRIP效应致塑性增量及其固溶温度依赖性[J]. 金属学报, 2019, 55(11): 1359-1366.
CHEN Lei, HAO Shuo, MEI Ruixue, JIA Wei, LI Wenquan, GUO Baofeng. Intrinsic Increment of Plasticity Induced by TRIP and Its Dependence on the Annealing Temperature in a Lean Duplex Stainless Steel[J]. Acta Metall Sin, 2019, 55(11): 1359-1366.

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摘要:

在Gleeble-3800试验机上进行了经1000~1200 ℃固溶处理后的节约型双相不锈钢(LDX)的拉伸变形实验，利用TEM分析了其加工硬化特性的微观机制，利用XRD测定计算了不同条件下形变诱导马氏体的饱和转变量。基于加工硬化规律对变形温度(室温~100 ℃)的敏感性，分别提出了室温变形时TRIP效应诱发塑性增量(或均匀延伸率增量)的量化指标：表观塑性增量( $Δ e$ )、单位体积马氏体诱发的平均塑性增量( $Δ e ˉ$ )及只与奥氏体稳定性有关的本征塑性增量( $Δ e *$ )，探讨了固溶温度对它们的影响规律。结果表明：LDX中形变诱导马氏体相变(SIMT)存有γ→ε→α′与γ→α′ 2种机制，引发TRIP效应并使LDX表现出“三阶段”加工硬化特征。不同固溶温度分别对应不同的临界变形温度(M_d)，使LDX在M_d温度变形时不存在TRIP，固溶温度越高，M_d越低、 $Δ e$ 越小。随着固溶温度增加， $Δ e ˉ$ 逐渐增加，而 $Δ e *$ 则逐渐减小，即奥氏体越稳定，TRIP本征增量越小。此外， $Δ e ˉ$ 与 $Δ e *$ 均与奥氏体稳定性系数(k)间存在一定的线性关系。

关键词 ：节约型双相不锈钢, 固溶温度, 形变诱导马氏体相变, TRIP效应, 塑性增量

Abstract：

Recently, advanced lean duplex stainless steels (LDXs) with exceptionally good tensile properties by transformation-induced plasticity (TRIP) have been developed to respond to the skyrocketing raw material cost. In these new alloys, TRIP in the metastable austenite phase is expected to dominate overall deformation of the steels. Solution annealing, as a critical step of production processing, affects the austenite characteristics in LDXs, such as volume fraction and mechanical stability of austenite, which in turn influences its TRIP behavior. In order to further develop advanced LDXs, an assessment in the plastic increment of TRIP and its dependence on solution treatment are necessary. In this work, the tensile deformation test of a LDX which was annealed in the range of 1000~1200 ℃ was carried out on a Gleeble-3800 machine. The microstructural mechanism of work hardening characteristics was characterized by TEM, and the saturation of strain-induced martensite (SIM) under different conditions was calculated by XRD. Some quantitative indicators which can characterize the plastic increment of TRIP were proposed, including apparent plastic increment ( $Δ e$ ), average plastic increment ( $Δ e ˉ$ ) induced by unit volume SIM and intrinsic plastic increment ( $Δ e *$ ) related only to mechanical stability of austenite. Meanwhile, their dependences on annealing temperature were discussed. The results show that SIM can develop in two ways of γ→ε→α′ and γ→α′ whereby the work hardening of the LDX exhibit a "three-stage" characteristic. There is a critical deformation temperature (M_d) where the TRIP is absent at every annealing temperatures. The higher the annealing temperature is, the smaller the M_d and the $Δ e$ are. As annealing temperature increases, $Δ e ˉ$ increases, while $Δ e *$ decreases, indicating a fact that the more stable the austenite is, the smaller the intrinsic plastic increment of TRIP is. In addition, both $Δ e ˉ$ and $Δ e *$ show a linear relationship with the austenite stability coefficient (k).

Key words： lean duplex stainless steel annealing temperature deformation-induced martensitic transformation TRIP effect plastic increment

收稿日期: 2019-04-10

ZTFLH:

TG142.1

基金资助:国家自然科学基金项目Nos(51675467);国家自然科学基金项目Nos(51675465);中国博士后科学基金项目Nos(2016M600194);中国博士后科学基金项目Nos(2017T100712);河北省自然科学基金项目No(E2016203284)

作者简介: 陈雷，男，1982年生，教授，博士

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https://www.ams.org.cn/CN/10.11900/0412.1961.2019.00108 或 https://www.ams.org.cn/CN/Y2019/V55/I11/1359

图1 2205钢在不同拉伸温度下的应力-应变曲线及加工硬化率曲线

图2 节约型双相不锈钢(LDX)与2205钢的拉伸变形曲线与加工硬化特征

图3 LDX拉伸断口附近微观组织的TEM像

图4 典型固溶温度下LDX经不同温度拉伸后的工程应力-工程应变曲线

表1 各条件下LDX的力学性能

图5 典型固溶温度下在室温和临界温度拉伸的真应力-真应变与加工硬化率曲线

T_a / ℃	M_d / ℃	Δe / %	V_γ	k	Δe^* / %	V_M	$Δ e ˉ$ / %
1000	80	25.8	0.48	4.39	0.538	0.410	0.629
1050	75	24.8	0.463	4.22	0.536	0.395	0.628
1100	70	23.6	0.446	3.98	0.529	0.374	0.631
1150	65	22.2	0.428	3.72	0.519	0.348	0.638
1200	60	20.8	0.410	3.38	0.507	0.320	0.649

表2 不同固溶温度下组织与力学性能及计算结果

图6 不同条件下LDX的XRD谱

图7 不同奥氏体稳定性下的本征塑性增量

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