Fe-Mn-C合金奥氏体强化对马氏体相变的影响

测定了5种Fe-Mn-C合金的M_s温度及奥氏体在M_s温度时的屈服强度,结果表明两者成线性关系。还研究了奥氏体固溶强化对马氏体形态的影响,提出存在一个奥氏体强化特征温度T_c,当M_s>T_c时,马氏体形态主要为位错型条状马氏体,当M_s<T_c时,主要为孪晶型片状马氏体,理论分析与实验结果符合。

Si对Fe-Mn-C合金的显微结构和拉伸性能的影响

以金相、X射线衍射和拉伸试验研究Si 对Fe-Mn-C合金显微结构和拉伸性能的影响。实验结果表明,Si有助于Fe-Mn-C合金在固溶状态形成退火孪晶,在形变中促使发生形变感生γ→ε马氏体转变和孪生切变。拉伸形变中形成的形变ε-马氏体相变强化和形变孪晶平和退火孪晶的应变强化,他Fe-Mn-C合金强度提高和塑性降低。

Ar-H_(2)O-H_(2)气氛下固态脱碳制备成分梯度中锰钢试验

为了研究Ar-H_(2)O-H_(2)气氛下含锰铁碳合金薄带在不同脱碳温度、气氛条件、薄带厚度对平均碳含量、薄带内部碳浓度梯度分布的影响,以Fe-12Mn-0.4C为研究对象,在Ar-H_(2)O-H_(2)气氛下进行脱碳试验,通过辉光放电来检测薄带内部碳元素分布。结果表明:在脱碳时间为10 min时,随着脱碳温度和P_(H_(2)O)/P_(H_(2))的升高,薄带内部碳浓度梯度增大;在脱碳时间为20和30min时,随着脱碳温度和P_(H_(2)O)/P_(H_(2))的升高,薄带内部碳浓度梯度呈先增大后减小的趋势;在不同脱碳时间下,薄带内部碳浓度梯度均随着薄带厚度的增加而降低。

Fe-Mn-C系γ→α相变驱动力计算

本文利用Hillert-Staffanson模型计算了Fe-1.33Mn-0.47C(at％)系Y→α相变驱动力G_v^Y→α。结果表明,ΔG_V^Y→α与温度的关系可以简单地表示为相关系数为0.9992。这一计算结果适用于成分与之相近的C-Mn钢和微合金钢的Y→α相变驱动力估算。

Fe-C-Mn-Si系合金马氏体转变开始温度的热力学计算

基于马氏体相变热力学和亚点阵模型,建立了Fe-C-Mn-Si系合金马氏体相变自由能表达式,并利用Compaq VisualFortran 6软件对其进行编程;应用Thermo-Calc软件及TQ6接口模块并结合大量实验数据,对计算参数进行优化,获得马氏体相变临界驱动力与Fe-C-Mn-Si系合金成分的关系式。采用该方法可较为准确地预测Fe-C-Mn-Si系合金的马氏体转变开始(Ms)温度,并有望推广到更多元合金体系。

Network structure and its effects on the strength of Fe-C-Si-Mn alloy castings

Fe-C-Si-Mn alloy castings used as blades in hydroelectric generators are studied and found to contain network structures after some heat treatments. Castings after annealing and normalizing were analyzed by microscope and transmission electron microscopy (TEM). The network formed during annealing was proved by TEM to be pearlite with very fine slices, while that formed during normalizing was proved by TEM and micro-hardness to be martensite or bainite. A theoretical analysis together with experimental studies has proved that the pearlite network is caused by carbon content increase in the interdendritic regions to which carbon atoms transfered from dendritic arms due to lower manganese content there during annealing, while the martensite or bainite network results from the higher hardenability of interdendritic regions where manganese content is higher. Experiments reveal that higher heating temperature or longer heating time enlarges the network size due to manganese homogenization. The network structure has a strengthening function like reinforcing rib, and the smaller the network size, the greater its strengthening capability.

新型生物可降解Fe-30Mn-1C合金的性能研究

采用真空感应熔炼法制备了Fe-30Mn-1C合金,研究了其力学性能、磁性、模拟体液中的降解速度以及体外生物相容性.研究结果表明,与Fe-30Mn合金和316L不锈钢相比,C的加入提高了铁基合金的力学性能,使材料兼具高强度和高塑性,并进一步降低了材料的磁性,使其具有更优良的核磁共振(MRI)兼容性.电化学阻抗谱(EIS)结果表明,材料的极化电阻降低,浸泡实验也证实材料的降解速度得到提高.体外生物相容性研究结果表明.Fe-30Mn-1C合金同时具有优异的抗溶血、凝血、血小板黏附性能,以及良好的细胞相容性,满足对医用植入材料的基本要求.