基于高速等温压缩试验构建普碳钢考虑温度弹跳的热变形本构方程

采用Gleeble3500型热模拟试验机,通过高速等温压缩试验所得的流变应力曲线以及温度变化曲线构建了传统热变形本构方程和考虑温度弹跳的热变形本构方程,并将它们与实测值进行对比,研究了普碳钢在热压缩变形过程中的温度弹跳以及其对构建本构方程精确度的影响。结果表明:在高速压缩过程中,由塑性功导致的温度弹跳使温度已严重偏离设定值,由塑性功转化热造成的温升与真应变呈线性关系,线性系数与设定的变形温度有关;构建的考虑温度弹跳的热变形本构方程比传统热变形本构方程的预测精度更高。

金属超塑变形本构方程中材料参数的识别

以 74 75Al合金为例 ,给出了用逆向求解技术确定包括 3种微观变形机制的超塑变形本构方程中的材料参数值 ,探索了目标函数式及参数初始值对最后优化结果的影响。

变形工艺对Q235钢热变形本构方程的影响

以Q235钢为对象,利用Gleeble-3500热模拟试验机研究其在不同变形工艺下的热变形本构方程。结果表明,Q235钢在不同变形工艺下的热变形本构方程受温度波动影响较大,较传统的方法测得的热变形本构方程,前者的计算结果更接近于实测值。

梁和框架结构的大变形非线性分析

描述了有限元方法分析梁和框架结构的几何非线性问题,考虑大转动的影响,在有限转动公式的级数展开式中,取二阶近似,从而形成线性刚度矩阵和几何刚度矩阵,推导了大变形情况下梁的本构方程,算例表明:对于较复杂的几何非线性问题,本文提出的方法是有效的。

800H合金热变形行为研究

通过高温单道次压缩实验,研究800H合金在变形温度850～1 050℃和应变速率0.01～10 s-1条件下的热变形行为和微观组织变化.根据单道次压缩实验数据,绘制了不同变形条件下的800H合金真应力-真应变曲线,通过非线性回归建立了流变应力数学模型;通过线性回归建立了不同温度区间内热变形本构方程.分析了热变形条件对合金微观组织的影响,结果表明:动态再结晶更有可能发生在低应变速率和高变形温度的变形条件下;当变形温度低于950℃时,沿晶界析出的Cr23C6粒子对动态再结晶的发生有一定的抑制作用.

高铝Ni_3Al基合金的热变形行为

采用Gleeble-3800型热模拟试验机研究了高铝Ni3Al基合金在变形温度为1200～1240℃,应变速率为0.01～1s-1条件下的热压缩变形,结果表明:在应变速率为0.01s-1时,高铝Ni3Al基合金对应的热变形本构方程为σ=28.57(lnε+6.72×105/RT-44.08),而当应变速率为0.1s-1和1s-1时,热变形本构方程为σ=28.57(lnε+1.28×106/RT-92.76)。变形过程中只有γ'相发生不同程度上回溶,但未发生动态再结晶。合金的最佳变形区间位于变形温度为1200～1215℃,应变速率为0.01s-1范围内;而当提高速率至1s-1附近,γ'相中塞积的位错容易造成单相γ'区中β/γ'界面的开裂,对应变形过程中的"失稳区"。

GH4049合金的热变形行为及组织演变

在Gleeble-1500热模拟机上进行GH4049合金的热压缩实验，获得合金在温度为1090～1180℃、应变速率为0．1~50s-1条件下的应力一应变曲线。对峰值应力进行线性回归获得合金在不同变形条件下的材料常数，通过非线性回归建立合金的热变形本构方程。结果表明：随着变形温度升高，动态再结晶更加充分，晶粒尺寸变大；随着应变速率增加，晶粒组织趋于均匀，晶粒尺寸先减小后增大。

GH625合金的热变形行为

采用Gleeble-1500热模拟试验机研究了GH625高温合金在应变速率为0.001～1 s-1、变形温度为1223～1373 K条件下的热变形行为。结果表明:当变形温度一定时,随应变速率的升高,合金的峰值应力σp和稳态流动应力σs及对应的应变εp和εs均升高;当变形速率一定时,随变形温度的升高,σp和σs以及εs均降低,但εp基本保持不变。GH625合金在热压缩变形过程中应变速率的降低和变形温度的升高均有利于动态再结晶的发生;根据应力-应变曲线,通过线性回归获得GH625合金的本构方程。

挤压态喷射成形GH738合金热变形行为及组织研究

在温度950~1150℃、应变速率0.001~1 s–1及工程应变50%条件下,利用Gleeble-3500TM热模拟试验机对挤压态喷射成形GH738合金进行热压缩实验,研究合金的流变应力,建立合金热变形本构关系,利用EBSD分析合金组织演变。结果表明:合金流变应力随温度的升高和应变速率的减小而降低,在相同变形条件下,具有细晶组织特征的挤压态喷射成形GH738合金峰值流变应力低于粗晶组织的铸锻GH738合金;挤压态喷射成形GH738合金热变形激活能为651.08 kJ·mol–1,GH738合金的热变形激活能随着初始平均晶粒尺寸的减小而升高;形变温度的升高使挤压态喷射成形GH738合金初始被拉长的晶粒逐渐演变为等轴再结晶晶粒,在1000℃以上获得完全动态再结晶组织,再结晶组织随形变温度的进一步升高发生长大。

基于热加工图的机床用双相不锈钢的热加工行为研究

采用Gleeble3800热模拟机对2205双相不锈钢进行高温热压缩变形实验,分析该材料在变形温度为950~1 100℃、应变速率为0.1~50.0 s^(-1),工程变形量为66.6%不变的条件下的流变应力变化规律。基于动态材料模型建立了2205双相不锈钢的热变形本构方程和热加工图,确定了失稳区。得到2205双相不锈钢热变形激活能Qdef=405.8 k J/mol,结合热加工图确定了最佳的热加工区间为变形温度为1 050~1 100℃,应变速率为0.1~1.0 s^(-1)。为2205双相不锈钢的热加工工艺提供依据。

7AXX铝合金在热压缩状态下的流变行为

研究7AXX铝合金在热变形过程中的流变行为对于提高专用设备锻件综合性能、避免材料热开裂有重要意义。本文利用Gleeble-3500热模拟试验机在变形温度360～460℃、应变速率0.001～1 s^(-1)的条件下,对7AXX铝合金铸锭进行高温压缩实验,研究了热压缩状态下温度和应变速率对该合金流变行为的影响程度,拟合得到了含Zener-Hollomon参数的7AXX铝合金流变应力表达式,建立了基于双曲正弦关系的合金热变形本构方程及热加工图。结果显示,变形温度及应变速率对7AXX铝合金的流变行为有显著影响。合金的流变应力随温度的升高而降低,随应变速率的增加而增加。合金在热压缩过程中的应力指数为3.21,热激活能为137.31 kJ/mol。变形温度385～450℃、应变速率0.01～0.1 s^(-1)是适用于7AXX铝合金的热加工条件范围。

热处理对汽车车身用5182铝合金板性能的影响

采用Gleeble3800热模拟机对5182铝合金进行压缩变形试验,分析了该合金在变形温度350～480℃、应变速率0.001～1 s-1、工程变形量为66.6%条件下的流变应力变化规律。基于动态材料模型建立了5182铝合金的热变形本构方程和热加工图,确定了失稳区,得到5182铝合金热变形激活能Qdef=160.46 k J/mol;根据热加工图确定了最佳的热加工区间变形温度355～450℃,应变速率0.1～0.001 s-1。对安全区内热加工后5182铝合金组织的微观形貌进行了研究,为该合金的热加工工艺制定提供了依据。

不同温度和应变速率下P92钢的高温拉伸特性

采用Instron5869拉伸试验机,在550~650℃、1×10^(-3)~1×10^(-5) s^(-1)应变速率条件下对P92钢进行了高温拉伸试验,分析了温度、应变速率对P92钢高温拉伸特性的影响,并得到了P92钢的本构方程,同时预测了1×10^(-4) s^(-1)和不同温度条件下的σ_(ε=0.1)值。结果表明:温度和应变速率是影响P92钢高温拉伸行为的两个重要因素,钢的强度随温度升高而降低,随应变速率增加而增大,断后伸长率和断面收缩率均随温度升高而增大;P92钢的变形激活能为92.24kJ·mol^(-1),不同温度下σ_(ε=0.1)的预测值与文献中的试验值比较吻合。

Processing map and hot deformation mechanism of novel nickel-free white copper alloy

Hot compression test of a novel nickel-free white alloy Cu?12Mn?15Zn?1.5Al?0.3Ti?0.14B?0.1Ce (mass fraction, %) was conducted on a Gleeble?1500 machine in the temperature range of 600?800 °C and the strain rate range of 0.01?10 s?1. The constitutive equation and hot processing map of the alloy were built up according to its hot deformation behavior and hot working characteristics. The deformation activation energy of the alloy is 203.005 kJ/mol. An instability region appears in the hot deformation temperature of 600?700 °C and the strain rate range of 0.32?10 s?1 when the true strain of the alloy is up to 0.7. Under the optimal hot deformation condition of 800 °C and 10 s?1 the prepared specimen has good surface quality and interior structure. The designed nickel-free alloy has very similar white chromaticity with the traditional white copper alloy (Cu?15Ni?24Zn?1.5Pb), and the color difference between them is less than 1.5, which can hardly be distinguished by human eyes.

Hot deformation behavior of as-quenched 7005 aluminum alloy

The compressive deformation behavior of as-quenched 7005 aluminum alloy was investigated at the temperature ranging from 250 °C to 450 °C and strain rate ranging from 0.0005 s-1 to 0.5 s^-1 on Gleeble-1500 thermal-simulation machine. Experimental results show that the flow stress of as-quenched 7005 alloy is affected by both deformation temperature and strain rate, which can be represented by a Zener-Hollomon parameter in an exponent-type equation. By comparing the calculated flow stress and the measured flow stress, the results show that the calculated flow stress agrees well with the experimental result. Based on a dynamic material model, the processing maps were constructed for the strains of 0.1, 0.3 and 0.5. The maps and microstructural examination revealed that the optimum hot working domain is 270-340 °C, 0.05-0.5 s^-1 with the reasonable dynamic recrystallization. The instability domain exhibits adiabatic shear bands and flow localization, which should be avoided during hot working in order to obtain satisfactory properties.

Hot deformation behavior of homogenized Al-3.2Mg-0.4Er aluminum alloy

The hot deformation behavior of the homogenized Al?3.2Mg?0.4Er aluminum alloy was investigated at 573?723 K under strain rates of 0.001?1 s?1. On the basis of compression experimental results, an accurate phenomenological constitutive equation that coupled the effects of strain rate, deformation temperature and strain was modeled. Furthermore, a kinetic model of dynamic recrystallization and processing map were also presented. The results show that the flow stress of the studied Al?3.2Mg?0.4Er alloy can be predicted accurately using the proposed constitutive model. The evolution of microstructure and the volume fraction of dynamic recrystallization can be described exactly in terms of S-curves with the proposed kinetic model. Moreover, the processing maps for hot working at different strains were constructed, suggesting the optimum processing conditions for this alloy are 573 K, 0.001 s?1 and 723 K, 0.001?0.1 s?1.

Hot deformation behavior and processing maps of Mg-Zn-Cu-Zr magnesium alloy

The deformation behaviors of a new quaternary Mg-6Zn-1.5Cu-0.5Zr alloy at temperatures of 523-673 K and strain rates of 0.001-1 s-1 were studied by compressive tests using a Gleeble 3800 thermal-simulator.The results show that the flow stress increases as the deformation temperature decreases or as the strain rate increases.A strain-dependent constitutive equation and a feed-forward back-propagation artificial neural network were used to predict flow stress,which showed good agreement with experimental data.The processing map suggests that the domains of 643-673 K and 0.001-0.01 s-1 are corresponded to optimum conditions for hot working of the T4-treated Mg-6Zn-1.5Cu-0.5Zr alloy.

S30432钢连铸和模铸管坯的高温加工性能对比

利用Gleeble热模拟试验机,完成了同炉冶炼的S30432钢连铸和模铸工艺生产的管坯在高温下的拉伸热变形过程,设置了1000、1050、1100、1150℃系列温度和0.1、1、5 s^(-1)应变速率的不同热模拟试验条件,获得了同炉冶炼的S30432钢连铸和模铸工艺生产的管坯在各个高温拉伸条件下的高温应力-应变曲线,并对其进行修正和拟合,使其尽可能符合实际试验情况。对同炉冶炼的S30432钢连铸管坯和模铸管坯的热变形本构方程进行了拟合,并对2种工艺管坯的高温热塑性差异进行对比分析。结果表明,连铸管坯和模铸管坯的热塑性在不同拉伸温度和速率下表现出一定规律性,连铸管坯的热塑性存在较大的波动,且整体上略逊于模铸管坯,为改进优化管坯的穿孔工艺提供了参考。通过扫描电镜对高温拉伸断口的微观组织结构进行表征,发现高温拉伸失效形式为塑性断裂,绝大部分断口形貌属于韧窝断口。然而,在特定条件下,部分连铸管坯试样表现出较差的热塑性,其断裂形式转变为脆性断裂。对于S30432钢连铸管坯的高温塑性加工,建议使用较高的应变速率和较高的应变温度以获得良好的加工性能。

Hot deformation behavior and processing map of Cu-Ni-Si-P alloy

The high-temperature deformation behavior of Cu-Ni-Si-P alloy was investigated by using the hot compression test in the temperature range of 600-800 ℃ and strain rate of 0.01-5 s-1. The hot deformation activation energy, Q, was calculated and the hot compression constitutive equation was established. The processing maps of the alloy were constructed based on the experiment data and the forging process parameters were then optimized based on the generated maps for forging process determination. The flow behavior and the microstructural mechanism of the alloy were studied. The flow stress of the Cu-Ni-Si-P alloy increases with increasing strain rate and decreasing deformation temperature, and the dynamic recrystallization temperature of alloy is around 700 ℃. The hot deformation activation energy for dynamic recrystallization is determined as 485.6 kJ/mol. The processing maps for the alloy obtained at strains of 0.3 and 0.5 were used to predict the instability regimes occurring at the strain rate more than 1 s-1 and low temperature （〈650 ℃）. The optimum range for the alloy hot deformation processing in the safe domain obtained from the processing map is 750-800 ℃ at the strain rate of 0.01-0.1 s i The characteristic microstructures predicted from the processing map agree well with the results of microstructural observations.

LNG用高锰超低温钢高温流变应力的温度依赖性

在800~1 000℃温度范围内,利用Gleeble-3800热模拟试验机对LNG用高锰钢进行应变速率为10/s的高温拉伸试验,研究了不同拉伸温度对流变应力及断裂机制的影响,建立了流变应力、应变速率及拉伸温度之间的本构方程。结果表明:断后试样的断面收缩率随着拉伸温度的升高而增加,而流变应力随之降低,由530 MPa降至312 MPa;断口韧窝的尺寸和深度随着温度的升高而增大,呈现晶界滑移和MnS、TiN、Al2O3等夹杂物脱落两种形貌。在应变速率为10/s、800~1 000℃温度范围内,LNG用高锰钢的热变形本构方程为ε=1.2×10^(19)[sinh(0.01σp)]^(4.4)exp[550.18×10^(3)],且该方程模型与实测值吻合程度较高。