Study on hot deformation behaviour of 316LN austenitic stainless steel based on hot processing map

Abstract

316LN is a type of austenitic stainless steel whose grain refinement only depends on hot deformation. The true stress–strain curves of 316LN were obtained by means of hot compression experiments conducted at a temperature range of 900–1200°C and at a strain rate range of 0·001–10 s^?1. The influence of deformation parameters on the microstructure of 316LN was analysed. Both the constitutive equation for 316LN and the model of grain size after dynamic recrystallisation were established, and the effect of different deformation conditions on the microstructure was analysed. The results show that the suitable working region is the one with a relatively higher deformation temperature and a lower strain rate, in which the dynamic recrystallisation is finely conducted. Moreover, the working region that should be avoided during hot deformation was indicated.     

Fe-8Mn-3Al-0.2C轻质高强钢的热变形行为

为了探究Fe-8Mn-3Al-0.2C轻质高强钢的热变形行为,在变形温度为1 123~1 423 K,应变速率0.01,0.1,1,10 s-1,真应变为0.6的条件下利用Gleeble-1500热模拟实验机进行热压缩模拟实验,通过实验机记录温度、真应力与真应变的关系,观察组织形貌演变规律.结果表明:流变应力曲线分为3个阶段,即加工硬化、动态软化及稳定流变应力;当变形温度升高和应变速率下降时,峰值应力及其所对应的临界应变减小,说明更容易发生动态再结晶;在变形初期ε0.1时,流变应力曲线出现应变增加而应力几乎保持不变的类屈服平台;压缩后的组织为奥氏体/铁素体双相组织,动态再结晶先在铁素体内部发生,随后由奥氏体承担;随着变形温度的升高和应变速率的下降,晶粒尺寸细化并趋于均匀,说明动态再结晶完成的更充分;本实验钢在本文处理工艺及0.6真应变下的最佳热加工工艺参数区间为1 250~1 400 K,应变速率为0.03~0.3 s~(-1);受合金元素影响,实验用钢的表观应力指数和热变形激活能分别为4.588 9和250.6 k J/mol,本构方程为ε·=6.20×10~9[sinh(0.009σ)]~(4.588 9)exp(-(250 601)/(8.314T)).     

Hot deformation behaviour and microstructure of a high-alloy gear steel

High strain isothermal compression tests at temperatures of 700–1200°C and strain rates of 0.1–50?s^?1 were performed in a Gleeble-3800 thermal simulator to investigate the hot deformation behaviour of a high-alloy Cr–Co–Mo–Ni gear steel, and the constitution equation and hot processing map were established based on these experiments. The results show that the flow stress can be described by the constitutive equation in hyperbolic sine function, and the optimum hot working regions are at the temperature of 1000–1100°C and strain rate of 0.3–1.0?s^?1. Optical microscopy observations of austenite grains indicate that dynamic recrystallisation occurs when the deformation temperature is over 900°C. The forging was successfully produced on the basis of the above-described researches.     

Cr-Mo-B系机械工程用钢高温流变行为及热加工图

在变形温度为850~1150℃、应变速率为0.1~10s -1 的条件下,对Cr-Mo-B系机械工程用钢进行高温热压缩实验。基于真应力-应变曲线,建立输入参数为温度、变形速率、应变和输出参数为流变应力的人工神经网络(ANN)模型。结果表明:神经网络模型的预测精度高,其预测流变应力的均方根误差为1.3858。根据动态材料模型理论(DMM),构建并分析材料在真应变为0.5和0.7时的热加工图,确定了最佳热变形工艺参数:当真应变ε=0.5时,变形温度为1050~1150℃、应变速率为0.1~0.4s -1 区域的功率耗散因子η≥37.20%;当真应变ε=0.7时,变形温度为1000~1150℃、应变速率为0.1~0.6s -1 区域的功率耗散因子η≥35.80%。     

新型Al-Zn-Mg-Sc-Er-Zr合金的热变形行为EI北大核心CSCD

采用Gleeble-3800热模拟机研究Al-8.9Zn-1.3Mg-0.1Sc-0.1Er-0.1Zr铝合金的热变形行为,构建温度380~440℃、应变速率0.01~10 s^(-1)区间内合金的热加工图,使用X射线衍射(XRD)、选区电子衍射(SAED)与能谱(EDS)对合金中存在的物相进行分析,并使用金相显微镜(OM)和透射电子显微镜(TEM)观察合金热变形后的微观组织。结果表明:合金的最佳热加工工艺参数区间为:400℃相似文献   

Hot deformation behavior and microstructural evolution of a modified 310 austenitic steel

To study the hot deformation behavior and microstructural evolution of a new modified 310 austenitic steel, hot compression tests were conducted at the temperature range from 800 to 1100 °C with strain rate of 0.1–10 s⁻¹ and strain of 30–70% using Gleeble 3500 thermal–mechanical simulator. The results showed that the serrated flow curves were caused by the competitive interaction between solute atoms and mobile dislocations. There were some coarsened precipitates on the high angle grain boundaries (HAGBs), which facilitated the nucleation of dynamic recrystallization grains. But these precipitates inhibited the growth of the recrystallization grains, and changed the deformation texture in the matrix. Low angle grain boundaries (LAGBs) decreased, while twin GBs and random HAGBs and increased as dynamic recrystallization occurred. Dynamic recrystallization occurred more readily at evaluated temperature or high strain rate. The true stress decreased with the reduction of LAGBs percent. The internal connections between mechanics and microstructures were also discussed.     

基于本构分析的中碳钒微合金钢热变形行为

采用Gleeble-1500热模拟试验机对一种中碳钒微合金钢在变形温度900~1 100℃、应变速率0.01~10 s-1条件下的热变形行为进行研究.分别建立了实验钢的幂律、指数和双曲正弦本构方程,观察了实验钢在不同变形条件下的显微组织,得出了实验钢的动态再结晶稳态晶粒尺寸和峰值应变与Zener-Hollomon参数的关系.结果表明:双曲正弦本构方程具有最高的拟合精度;实验钢热变形激活能Q为273.225 kJ/mol,与奥氏体的自扩散激活能(270 kJ/mol)十分接近,说明实验钢在此变形条件下的速率控制机制是扩散控制的位错攀移;显微组织观察表明,实验钢的动态再结晶行为受变形温度和应变速率的影响;拟合得出实验钢的动态再结晶稳态晶粒尺寸(Ds)和峰值应变与Z参数的关系为ln Ds=-0.200 31ln Z+7.941 65和lnεp=0.184 56ln Z-5.373 83.     

Hot working behavior of 2205 austenite-ferrite duplex stainless steel characterized by constitutive equations and processing maps

The hot deformation characteristics of the 2205 duplex stainless steel were analyzed using constitutive equations and processing maps. The hot compression tests were performed at temperature range of 950-1200 °C and strain rate of 0.001-1 s⁻¹. Flow stress was modeled by the constitutive equation of hyperbolic sine function. However, the stress exponent and strain rate sensitivity were different at low and high deformation temperatures where austenite and ferrite are dominant, respectively. It was recognized that strain at the peak point of flow curve increases with the Zener-Hollomon parameter, Z, at low temperature deformation while at high temperature deformation it actually decreases with Z. The power dissipation map, instability map and processing map were developed for the typical strain of 0.3. It was realized that dynamic restoration mechanisms could efficiently hinder the occurrence of flow instability at low and medium strain rates. Otherwise, the increase in strain rate at low and high temperatures could increase the risk of flow instability.     

Study on hot workability and optimization of process parameters of a modified 310 austenitic stainless steel using processing maps

To investigate the optimized hot deformation parameters of a modified 310 austenitic stainless steel, the hot compression tests were performed using a Gleeble 3500 thermal simulator. The hot deformation behavior and hot workability characteristics were investigated in a temperature range of 800–1100 °C and a strain rate range of 0.1–10 s⁻¹. The hot processing maps of the tested steel were developed based on the dynamic material model (DMM), from which the safe deformation regions and instable deformation regions were determined. The corresponding microstructural and hardness evolutions during deformation were analyzed in detail. It was found that the deformation in the safe regions was beneficial to dynamic recovery (DRY) and dynamic recrystallization (DRX), while the deformation in unstable region would lead to flow instability, kink boundaries and grain growth. Near 950 °C, the energy dissipation rates were unusually lower, and the hardness of the deformed sample exhibited a significant increase, as a result of strain-induced precipitation. Coupled with the microstructure analysis and processing map technology, the workability map was schematically plotted and the optimal working conditions were determined. Such conditions were: temperatures in the range of 1075–1100 °C and strain rates in the range of 0.5–1.7 s⁻¹. These conditions are critical to attain an excellent homogeneous microstructure with fine grains after deformation for the modified 310 austenitic stainless steel.     

AlFeCoNiMo0.2高熵合金热变形行为及热加工图

目的 确定AlFeCoNiMo0.2高熵合金的热加工工艺参数,为该合金热挤压工艺的制定及优化提供有效依据.方法 采用Gleeble-3800热模拟试验机,在变形温度为900～1150℃,应变速率为0.001～1 s-1,真应变量为0.6的条件下对AlFeCoNiMo0.2高熵合金进行热压缩实验.基于Arrhennius模型对热压缩实验数据进行拟合,建立AlFeCoNiMo0.2高熵合金的Arrhennius本构方程,并绘制AlFeCoNiMo0.2高熵合金在不同真应变下的热加工图.结果 AlFeCoNiMo0.2高熵合金的流变应力值与应变速率呈正相关,与变形温度呈负相关;Arrhennius热变形本构方程的平均相对误差为3.97％;该合金热加工图中的流变失稳区分别为900～1120℃/0.1～1 s-1和1120～1150℃/0.2～1 s-1;热加工安全区为1075～1150℃/0.001～0.01 s-1;最佳热加工工艺参数为:1090～1125℃/0.001～0.002 s-1.结论 AlFeCoNiMo0.2高熵合金的热变形过程为加工硬化和动态再结晶为主的动态软化,建立的Arrhennius本构方程可较好地描述该合金的热变形行为,绘制的热加工图可为该合金热挤压工艺的制定及优化提供有效指导.     

Mg-9Al-3Si-0.375Sr-0.78Y合金的热变形行为及本构模型

利用Gleeble-3500热模拟试验机对Mg-9Al-3Si-0.375Sr-0.78Y合金试样进行等温恒应变速率压缩实验,研究其在温度250~400℃、应变速率0.001~10s~(-1)条件下的热变形行为。结果表明:在热变形过程中,峰值应力随着应变速率的降低和温度的升高而减小,且峰值应力对应变速率的敏感性随着变形温度的下降而增强。建立了考虑应变的热变形Arrhenius本构模型,模型精度良好,在300,350℃及0.001~10s~(-1)范围内,模型的平均绝对误差分别为1.57%和1.76%;合金的平均变形激活能为183.58k J/mol,平均应变速率敏感指数为0.1616。热变形过程中,α-Mg相呈现明显的动态再结晶特征,β-Mg₁₇Al₁₂相尺寸减小且分布均匀,初生Mg_2Si相较小。在低温(250~300℃)变形时,动态再结晶仅发生在晶界处。在高温(350~400℃)变形时,初生α-Mg晶粒发生了明显的动态再结晶。随着温度的增加和应变速率的降低,再结晶程度提高,再结晶晶粒逐渐长大。     

锻态GH4169合金热变形本构方程及热加工图

目的 研究锻态GH4169合金的热变形行为,获得优化的热加工参数。方法 采用Gleeble 3500热模拟实验机对锻态GH4169合金进行不同工艺参数的热压缩实验,建立锻态GH4169合金的热变形本构方程,分析流变应力与热加工参数之间的关系。根据获得的流变应力–应变曲线建立锻态GH4169合金的热加工图。采用金相显微镜观察锻态GH4169合金变形后的显微组织。结果 锻态GH4169合金的应力随变形温度的增加和应变速率的降低而降低。基于锻态GH4169合金的热加工图可知,锻态GH4169合金可热加工的区域分别为987～1 027℃/0.026～0.01 s^-1和1 070～1 100℃/0.026～0.01 s^-1,最优热加工参数分别为1 000℃/0.01 s^-1和1100℃/0.01s^-1。通过金相组织结果分析可知,锻态GH4169合金无论在低温高应变速率条件下,还是在高温低应变速率条件下都发生了再结晶。对于热加工图中的流变失稳区,合金的动态再结晶主要与变形热有关。对于热加工图中可热加工的区域,合...     

冷拔态GH4738合金热变形本构方程及热加工图

目的 研究紧固件用冷拔态GH4738合金棒材在不同工艺参数下的热变形行为,为紧固件热加工工艺参数优化提供理论指导。方法 采用Gleeble-3500热模拟实验机对冷拔态GH4738合金棒材在变形温度1 000~1 080 ℃、应变速率1~10 s⁻¹条件下进行了热压缩实验,变形量为50%。计算了该合金的材料常数和变形激活能Q,建立了基于峰值应力的冷拔态GH4738合金的本构方程,根据动态材料模型理论绘制了冷拔态GH4738合金的能量耗散图和失稳图,获得了合金在不同应变下的热加工图,并讨论了显微组织演变情况。结果 冷拔态GH4738合金的流变应力随着变形温度的增加或应变速率的减小而降低。线性回归的相关系数证实了描述该材料热变形行为的本构方程的准确性。基于冷拔态GH4738合金的热加工图及显微组织验证结果可得,冷拔态GH4738合金的主要失稳区工艺参数区间为1 000~1 035℃/0.12~3 s⁻¹,1 030~1 072℃/ 0.25~10 s⁻¹和1 075~1 080 ℃/2.72~10 s⁻¹。热加工较佳工艺条件为1 000~1 028 ℃/0.02~0.14 s⁻¹和1 040~1 080 ℃/ 0.06~0.74 s⁻¹。结论 通过对冷拔态GH4738合金热变形本构方程和热加工图进行研究,获得了冷拔态GH4738合金优化的热变形工艺参数,可用于指导冷拔态GH4738合金的紧固件热加工成形。     

A100钢的热变形行为及加工图

目的 研究A100钢的热变形行为,确定热加工范围并优化工艺参数.方法 使用Gleeble-3800热模拟实验机,对A100钢进行应变为0.6,变形温度为1073～1473 K,应变速率为0.01～10 s–1的等温热压缩实验.利用A100钢的热压缩实验数据,建立在不同变形温度、不同应变速率下的真应力-真应变曲线.建立A100钢基于唯象的本构模型与基于物理的本构模型以及基于Murty失稳准则的热加工图.结果 当应变速率一定,温度升高或一定,应变速率下降时,A100钢的流变应力会减小,流变应力曲线上主要表现为动态再结晶的软化机制.结论 构建的基于唯象的本构方程可以对A100钢在应变为0.6时的流变应力进行较好的预测,基于物理的本构方程可以反映出A100钢的物理特性,通过构建的基于Murty失稳准则的加工图可以得到A100钢的加工范围是温度为1173～1223 K,应变速率为0.01～0.1 s–1和温度为1323～1373 K,应变速率为0.05～0.15 s–1时.     

含稀土H13钢热变形行为及热加工图研究

利用Gleeble-3800热力模拟试验机在900~1 200℃、0.01~10s~(-1)的实验条件下,对含稀土H13进行了热压缩。根据获取的流变应力曲线,建立了含稀土H13钢的高温热变形本构方程及热加工图,并分析了变形后的金相组织。结果表明,在高应变速率下流变应力曲线说明了含稀土H13钢具有断续再结晶行为,稀土的加入显著提升了H13钢的应力值,经计算含稀土H13钢的热激活能为573kJ/mol,适宜的热加工参数为1 050~1 200℃、应变速率0.01~1s~(-1)。稀土的加入拓宽了H13钢的热加工参数范围。     

铸态Mg−2Sc−2Y−0.5Zr合金热压缩行为及热加工图

目的 研究铸态合金Mg?2Sc?2Y?0.5Zr合金热压缩行为及热加工图,根据合金的用途和再结晶程度,确定最佳热加工艺参数,为合金后续变形提供参考。方法 通过实验设计合金成分,称取一定质量的纯镁锭和二元中间合金,在真空熔炼炉中加热至760 ℃,保温至熔化,搅拌,静止,然后在钢磨具中空冷,得到合金锭。实际成分通过电感耦合等离子体原子发射光谱法测定;切取合适大小的铸锭进行X射线衍射实验。用于热压缩的铸态样品为圆柱形试样(?10 mm×15 mm) ,在进行热压缩实验前,对所有样品表面进行抛光。使用Gleeble?3800热压缩模拟试验机对铸态Mg?2Sc?2Y?0.5Zr合金进行热压缩试验,变形温度为573~723 K,应变速率为0.001~1 s^?1。经热压缩后将各试样立即进行水淬,以保持压缩变形组织。将压缩样品沿着纵轴切割压缩样品,然后抛光、蚀刻,并使用扫描显微镜进行检查,以观察微观结构的演变,计算该合金的变形激活能,并构建合金高温变形的本构方程,建立真应变为0.5时的热加工图。结果 得到了铸态Mg?2Sc?2Y?0.5Zr合金热变形本构方程及真应变为0.5时的热加工图,合金热变形发生了动态回复和动态再结晶,合金的热变形激活能Q为198.58 kJ/mol。结论 根据用途和再结晶程度,铸态Mg?2Sc?2Y?0.5Zr合金的最佳加工参数为变形温度623~673 K、应变速率0.001~0.01 s^?1,以及变形温度723 K、应变速率0.001~1 s^?1。