两相区退火温度对低碳低硅TRIP钢组织和性能的影响

研究了0.11C-0.6Si-1.5Mn冷轧TRIP钢两相区退火温度对组织和力学性能的影响,结果表明,试验钢经780℃退火5 min和400℃等温5min处理后可以获得10％的残余奥氏体,较低或较高的退火温度都将使残余奥氏体量略微下降。当试验钢处理后的铁素体量为70％时,可以获得好的相变诱发塑性和好的强韧性配合,其强塑积可达21000 MPa·％。试验钢的应变硬化指数n值与铁素体量有好的相关性,随铁素体量的下降而下降,残余奥氏体量对其影响不大。     

退火温度对0.2C-1.5Si-1.5Mn-(0.5Cu)TRIP 钢组织的影响

用彩色金相法、X 射线衍射、扫描电镜研究了成分(%)为 0.2C-1.5Si-1.5Mn和0.2C-1.5Si-1.5Mn-0.5Cu TRIP钢 750～780℃不同退火温度对组织的影响。结果表明,含0.5 %Cu TRIP钢750℃、760℃、780℃退火的残余奥氏体体积含量为15.2 %～17.2 % ,770℃退火为15.2 %～15.7% ;不含CuTRIP钢760℃和770℃退火的残余奥氏体体积含量分别为12.5 %～12.9%和14.6 %～15.1% ,低于750℃和780℃退火的奥氏体量分别为17.0 %～17.5%和16.0 %～16.4%。随退火温度由750℃提高至780℃ ,两种钢中的铁素体量由～70%降至～5 0% ,贝氏体量由～10%增至～30%     

退火温度对退火马氏体基TRIP钢显微组织和力学性能的影响

将C-Si-Mn系TRIP钢通过完全淬火和两相区退火相结合的工艺,得到一种以退火马氏体为基体的TRIP钢（简称TAM钢）,并对比分析了TAM钢在不同温度退火后的显微组织和力学性能.结果表明,TAM钢经退火后的显微组织特征为精细规整的板条退火马氏体基体、片状残余奥氏体和贝氏体/马氏体组成的混合组织.这种组织降低了基体的硬度以及基体和第二相之间的强度比,减少了基体的位错密度.随着退火温度的提高,退火马氏体基体的板条形态逐渐消失,新生马氏体/贝氏体的团状混合组织逐渐增多.当退火温度为780℃时,综合力学性能优异,抗拉强度为1130 MPa,延伸率可达20%,强塑积为22600 MPa·%.当退火温度较低时,残余奥氏体主要以片状存在于退火马氏体板条间,有利于TRIP效应的发生.     

临界区退火温度对Nb-Cr-RE系微碳DP钢组织及性能的影响

实验室设计了Nb-Cr-RE系微碳DP钢,利用扫描电镜以及拉伸试验机,观察与分析了退火温度对微碳DP钢组织与性能的影响.结果表明:微碳DP钢退火板主要由铁素体及其晶界上附着的细小马氏体所构成;随退火温度的上升,DP钢的抗拉强度先升后降,屈服强度逐渐降低,伸长率先增加后降低;铁素体再结晶越充分,晶粒尺寸分布越均匀,等轴化越明显,DP钢屈服强度越小,伸长率越高;另外高温退火时的较大尺寸短棒状碳化物会明显恶化伸长率.      

两相区退火时间对热轧汽车用超细晶亚稳钢析出物的影响

采用碳萃取复型技术和采用透射电镜TEM+EDX技术研究分析汽车用超细晶亚稳钢热轧板和两相区不同退火时间钢板中析出物的尺寸、形态、分布和成分组成。结果表明:热轧板中主要析出物为类似正方形TiN、椭圆状NbTi(CN)和细小圆球状NbC,TiN析出于浇铸过程,在轧制冷却过程中,Nb、C元素以TiN粒子为形核点析出的复杂析出相NbTi(CN),NbC析出于位错与亚晶界处;在两相区退火过程中,部分碳化物固溶于奥氏体中,未固溶的析出物相互吞并粗化,为典型的Oswald熟化机制;在两相区退火初期,有矩形TiN析出物析出,随着退火时间的延长,析出物形貌向圆形和椭圆形发展,进一步粗化,保温6 h以后,析出物为NbTi(CN)和NbC,未发现TiN析出物。     

780MPa级热镀锌用TRIP钢退火工艺及组织演变

研究了热镀锌用高强TRIP钢的退火工艺对性能的影响和组织演变规律.结果表明:实验用钢可获得780.00MPa以上的抗拉强度和24.00%以上的断后延伸率;两相区加热温度和贝氏体保温时间对钢的力学性能具有显著影响,两相区加热温度为850℃,贝氏体保温时间为30s时,实验用钢能获得最佳的综合力学性能;在贝氏体中温相变后,仍有部分亚稳奥氏体(碳含量较低)在后续冷却过程中发生马氏体相变,从而导致钢退火后的微观组织由铁素体、贝氏体、残余奥氏体和马氏体组成.     

低碳中锰热轧TRIP钢退火工艺及组织演变

研究了第三代高强度高塑性TRIP钢的退火工艺对性能的影响和组织演变规律.热轧后形成的原始马氏体与临界退火时形成的残余奥氏体使TRIP钢具有良好的强度和塑性.结果表明:实验用钢可获得1000MPa以上的抗拉强度和30%以上的断后延伸率,且强塑积>30 Gpa·%;退火温度和保温时间对钢的力学性能具有显著影响,热轧TRIP钢临界退火温度为630℃,保温时间18 h时,实验用钢能获得最佳的综合力学性能.     

冷轧TRIP800钢的组织性能和形变行为

 采用Gleeble 3800热模拟机、MTS拉伸实验机、LEO1450携带EBSD系统的扫描电镜与高倍电镜等对TRIP800进行了组织性能考察,并对其形变过程裂纹走向与断裂机理进行了观察分析。结果表明,实验钢退火加热温度为840 ℃,保温120 s后获得最优力学性能。其残余奥氏体晶粒主要分布在晶界处,且尺寸在3 μm以下。原位拉伸时,当试样裂纹尖端遇到残余奥氏体时,应力集中促使马氏体转变,裂纹尖端被钝化,产生TRIP效应。最后,试样断口中部为剪切断裂,边部为塑性断裂。     

终轧温度对低硅含磷系TRIP钢组织性能的影响

通过实验室热轧试验,研究了不同终轧温度下低硅含磷系热轧TRIP钢的组织特征及性能特点。结果表明：终轧温度由900℃降低到790℃,铁素体体积分数增加,贝氏体体积分数降低,残余奥氏体体积分数变化不太明显;终轧温度900和820℃时,得到贝氏体为基体的室温组织;终轧温度降低到790℃时,低温变形促进了奥氏体到铁素体的相变率...     

连续退火温度对高硅双相钢组织及性能影响

 用连续退火模拟试验机,在实验室试制了冷轧高硅DP590,并通过扫描电镜、EBSD、透射电镜和力学性能测试研究了不同退火温度（735~835℃）对其组织和力学性能的影响。结果表明：退火温度对高硅双相钢强度和塑性有重要的影响,当退火温度为785℃时,材料获得良好的综合力学性能。不同温度退火后得到的组织均为铁素体和均匀分布在其晶界上的岛状马氏体;利用EBSD技术清晰地观察到离散分布于铁素体和马氏体晶界处的残余奥氏体。运用透射电镜观察到马氏体周围的位错线及位错团,这是双相钢连续屈服特性的重要保障。     

Influence of intercritical annealing temperature on microstructure and mechanical properties of medium Mn TRIP steel

The transformation, microstructure and mechanical properties of the 0. 2C- 5Mn TRIP steel after intercritical annealing were investigated using dilatometer, scanning electronic microscopy (SEM), transmission electron microscopy(TEM), X- ray diffraction (XRD), and tensile testing machine. The phase transformation thermodynamics of the investigated steel after intercritical annealing was calculated by Factsage software and the characteristics of the transformation were discussed. The results show that the reversed austenite content increases with the increasing of the intercritical annealing temperature, the carbon content in reversed austenite firstly increases and then decreases, manganese content in reversed austenite decreases, which results in the decreasing of the thermal stability of reversed austenite. When the intercritical annealing temperature is 700??, an obvious martensitic transformation occurs during the cooling process. With the increasing of intercritical annealing temperature, cementite is gradually dissolved, but it cannot be completely dissolved due to the short transformation time. When the intercritical annealing temperature is 600-675??, the microstructure after intercritical annealing consists of ferrite, cementite and retained austenite. When the intercritical annealing temperature is 700??, the microstructure after intercritical annealing consists of ferrite, retained austenite, martensite and a small amount of undissolved cementite. The engineering stress and strain curves of the investigated steel are significantly changed with increasing intercritical annealing temperature. At the same time, the optimal mechanical properties with tensile strength of 1138MPa and total elongation of 23% can be obtained after annealed at 675?? for 3min.     

Effect of intercritical annealing temperature and cooling rate on the microstructure and mechanical properties of low-carbon aluminum killed steel

In this study,the intercritical annealing process for a typical low-carbon aluminum killed steel is investigated.A cold-rolled sheet was annealed at intercritical temperatures ranging from 730 ℃ to 770 ℃ and then cooled in air or water.The annealed steel was then baked at 210 ℃,and its mechanical properties and microstructures were analyzed in detail.It is shown that after the air-cooling process,the strength of steel decreased and ductility increased with an increase in the annealing temperature.However,after water-cooling,the strength and ductility both increased with the increase of annealing temperature.These results are attributed to the propertyoptimization of the steel.     

Effect of warm- rolling and intercritical annealing on microstructure and mechanical properties of medium- Mn steel

Effect of warm- rolling and subsequent intercritical annealing time at 650?? on microstructure and mechanical properties of a medium- Mn steel 0. 1C- 5Mn was investigated by using uniaxial tensile testing, transmission electron microscopy (TEM) and X- ray diffraction (XRD) analysis. The results show that a duplex microstructure having both equiaxed and lamellar morphologies of reverted austenite and ferrite is obtained after intercritical annealing of the warm- rolled steel sheet. The amount of reverted austenite and its size increase with increasing annealing time, which causes a decrease of the mechanical stability of austenite and thus an increase of ultimate tensile strength (UTS) while a decrease of yield strength, total elongation (TEL) and the product of UTS to TEL (UTS??TEL). An excellent combination of strength and ductility of 40GPa??% could be obtained after a short time annealing of 5min. The combination of strength and ductility (UTS??TEL) could be increased by about 20% for the warm- rolled steel sheet compared to that of the cold- rolled steel sheet. It is thus proposed that warm- rolling is a promising way to simplify the traditional multi- stage rolling and annealing processes of medium- Mn steels as well as further enhancing it mechanical properties.     

连续退火的无Si TRIP钢的组织和力学性能

在实验室用Gleeble3500热模拟试验机制备了一种无Si TRIP钢.利用拉伸试验机、扫描电镜、透射电镜、X射线衍射以及热膨胀仪对其力学性能、微观组织和相变规律进行研究,在此基础上分析了贝氏体相变温度和时间对力学性能和残余奥氏体的影响.无Si TRIP钢呈现出良好的整体力学性能,抗拉强度分布在740~810 MPa,延伸率均在25%以上,最高可达32%以上;贝氏体等温温度为420℃时能获得最佳的综合力学性能,抗拉强度随贝氏体相变时间增加而下降,延伸率随之上升,而屈服强度没有显著变化.无Si TRIP制的铁素体晶粒大小约为3~4μm,比含Si TRIP钢铁素体晶粒细小;残余奥氏体的体积分数在8%~10%,比含Si TRIP钢低约3%;420℃保温300 s后贝氏体相变基本结束,而碳的扩散仍然在进行;无Si TRIP钢贝氏体相变速率比含Si TRIP钢快,贝氏体相变总量也更多.     

固溶温度对中锰TRIP钢组织与力学性能的影响

以w(Mn)=8%的热轧TRIP钢(即相变诱导塑性钢)为对象,研究了热处理工艺对其显微组织与力学性能的影响规律.该中锰TRIP钢在固溶温度为800℃时,可获得包括铁素体、马氏体、残余奥氏体的多相组织.与一般TRIP钢相比,其力学性能明显提高,在固溶加回火的条件下,实验钢的抗拉强度为800～1 000 MPa,延伸率达到31%～40%,而强塑积达(30～32)GPa%.     

退火温度对超细晶中锰TRIP钢组织性能的影响

为研究连续退火工艺生产中锰TRIP钢汽车板的可行性,在钢板连续退火模拟机CCT-AY-域上研究了590~710℃不同退火温度下保温3 min对低碳中锰钢组织性能的影响.利用扫描电镜、透射电镜、电子背散射衍射和X射线能谱分析等微观分析方法对实验钢进行了组织结构和成分表征,利用X射线衍射法测量了残余奥氏体量,通过拉伸试验机测试了钢的单轴拉伸性能.结果表明：保温3 min时,随着保温温度的升高,残奥含量先增加后减少.在650℃退火时断后伸长率（21.3%）和强塑积（28 GPa·%）获得最大值,抗拉强度达到1330 MPa.马氏体基体通过回复,而残余奥氏体通过孪晶,获得超细晶组织.亚稳奥氏体的TRIP效应和超细晶铁素体（马氏体）共同提供了实验钢高的塑性.实验钢真实应力-应变曲线上呈现锯齿状现象,且稳定阶段加工硬化指数远高于传统TRIP钢.     

铌微合金化对高Al冷轧TRIP钢组织与力学性能的影响

采用二段式盐浴热处理、金相显微镜(OM)、扫描电镜(SEM)、X射线衍射(XRD)和拉伸实验等方法,研究了添加0.025%微合金元素Nb对高Al(1.5%Al)冷轧相变诱导塑性钢(TRIP)组织与性能的影响规律.结果表明:Nb微合金化使高Al冷轧TRIP钢在连续退火后组织得到细化,残余奥氏体含量及其碳含量比无Nb钢均有所升高.含Nb钢在370℃和400℃等温后抗拉强度均大于650MPa,且总伸长率达到35%,具有优异的综合力学性能.Nb微合金化,将本实验所研究的高Al冷轧TRIP钢的最优贝氏体区等温温度由400℃左右扩大到370~400℃,提高了生产的工艺稳定性.     

临界区退火处理对0.15C-1.5Mn-1.5Al冷轧TRIP钢相变和力学性能的影响

利用热膨胀仪、热处理实验、拉伸实验和X衍射实验研究了不同临界退火温度对0.15C-1.5Mn-1.5Al TRIP钢相变、残余奥氏体特征和力学性能的影响.结果表明:不同临界退火温度下的热膨胀曲线具有相同的变化过程,两相区奥氏体含量随临界退火温度的升高而上升,而其碳含量则下降;临界退火温度影响试样的残余奥氏体特征和力学性能,820℃退火处理时残余奥氏体的体积分数为14%,碳的质量分数为1.36%;力学性能也是820℃退火时最佳,强塑积可达25400 MPa·%,且变形过程中具有高的瞬时加工硬化指数(n值).     

Microstructure and Mechanical Properties of High Manganese TRIP Steel

 Abstract： Microstructure evolution and mechanical properties of newly designed 01C-6Mn-05Si-1Al TRIP-aided steels under different annealing conditions and the effects of matrix microstructure before intercritical annealing on the final microstructure were studied by means of X-ray diffraction (XRD), scanning electron microcopy (SEM), dilatometric simulation, optical microstructure (OM) and tensile testing in this work. The experimental results indicate that the TRIP steel with Mn of 6% could form a considerable amount of retained austenite with good TRIP effect after a simple intercritical annealing treatment, and the matrix microstructure before intercritical annealing treatment can greatly affect the final microstructure. The original microstructure of the ferritic matrix steel was eliminated, while annealed martensite was remained from the martensite matrix steel under the same intercritical annealing conditions.