Influence of heat treatment on fracture and magnetic properties of radially oriented Sm2Co17 permanent magnets

The quenching, fracture and aging treatment of radially oriented Sm2Co17 ring magnets were investigated. The results indicate that the ring magnets have obvious anisotropy of thermal expansion, which easily leads to the splits of the magnets during quenching. The fracture is brittle cleavage fracture. The difference （Aa） of the expansion coefficient reaches the maximum value at 800-850 ℃. So, various quenching processes at different steps are adopted in order to reduce the splits. When the magnets are aged, 1：5 phase precipitates from the 2：17 matrix phase and forms a cellular microstructure with 2：17 phase. BHmax and JHc reach the maximum value 226 kJ/m^3 and 2 170 kA/m after being aged at 850 ℃ for 4 h and 8 h, respectively. The aging treatment at 850 ℃ has little influence on remanence（Br）, which can always keep a high value （≥1.0 T）. Through appropriate heat treatment, the ring magnets have uniform cellular microstructure and excellent magnetic properties： Br ≥ 1.0T, JHc ≥2 100 kA/m, BHmax ≥ 220 kJ/m^3.     

Preparation and electrochemical performance of nanosized Co3O4 via hydrothermal method

The hydrotalcite-type cobalt compounds were prepared through oxidation of Co（OH）2 gel using NH4OH as precipitating agent and H2O2 as oxidant. These hydrotalcite-type cobalt compounds were transformed into Co3O4 through hydrothermal decomposition with nanostructural deformation. The precursor and product were characterized by Fourier-transform infrared（FT-IR） spectrum, X-ray diffractometry（XRD） and transmission electron microscopy（TEM）. The electrochemical performances of as-prepared nanosized Co3O4 as anode materials in lithium-ion batteries were tested by charge-discharge test in the voltage range of 0-3.0 V. The influence of morphology of Co3O4 particle on the capacity and cycling performance was studied. The results show that the shape and size of the final product can be controlled by altering cobalt sources. The irregular cubic Co3O4 with the average particle size of about 10 nm shows the best electrochemical performance. After 10 charge-discharge cycles, the specific charge capacity retains 555 mA.h/g.     

用攀枝花钛矿和云南钛矿冶炼钛渣工业试验研究

通过磁性测量和X-射线衍射研究了Gd2(Co，Al)17化合物的结构和磁晶各向异性。当x≤4时，样品具有菱方Th2znl7型结构，x=5时，具有六方CaCu5型结构。随着Al浓度增加，晶格常数和单胞体积单调增大，而居里温度和自发磁化强度近似线性地减小；在x≥l时，观察到Co亚点阵的磁晶各向异性变号，室温易磁化方向由易面转变为易轴，且易轴各向异性场和各向异性常数随Al原子浓度增加出现极大值；基于补偿温度(65K)下自由粉末颗粒的磁化曲线，导出了亚点阵间的分子场系数和Gd-co交换耦合常数，结果表明，Al原子对Gd-Co交换耦合作用的影响较小。根据Al原子在Co亚点阵4种晶位的择优占位，分析了磁晶各向异性的演变。     

镍基合金激光直接制造的显微组织与缺陷分析

采用FGH95镍基高温合金粉末进行激光直接制造工艺实验，研究了不同工艺参数对表面形貌、显微组织和显微硬度的影响。结果表明，成形件表面平整无变形，显微组织为细小而致密的柱状晶。有层内生长和外延式生长两种生长方式。同时对其中出现的缺陷也作了研究分析，得到了优化的工艺参数。     

La0.6Sr0.4Co1-yFeyO3钙钛矿复合氧化物的结构与电学性能

采用固相反应法合成出La0.6Sr0.4Co1-yFeyO3体系复合氧化物样品，XRD分析结果证实不同Co／Fe比例的样品中均形成菱形六面体钙钛矿结构，采用固相烧结法制备出致密的La0.6Sr0.4Co1-yFeyO3体系陶瓷。研究结果表明，在室温到900℃温度范围内La0.4Sr0.4CoO3(y=0)的电导率随温度的增加而单调降低，其它Co／Fe比例样品的电导率随着温度的增加出现最大值，电导率达到最大值的温度随Co／Fe比例的降低而提高。在低温段，La0.6Sr0.4Co1-yFeyO3体系的导电行为符合小极子导电机制，导电活化能随Co／Fe比例的降低而增加。     

高密度钨合金热静液挤压流动粘度的数值计算

采用粘性流体的运动微分方程分析工作介质在锥模中的挤压流动，通过分析工作介质的粘度对热静液挤压的影响，指出了合理的选择工作介质的成分使得粘度适宜，可以使热静液挤压力最小，而且能够避免挤压件缺陷的产生。挤压介质的粘度是关系到坯料变形流动的润滑性能及挤压变形流动性能的关键。在此基础上，给出了挤压介质的粘度的数学关系式，为热静液挤压工艺奠定重要的理论基础。     

反应堆A0纯铝的点蚀模拟

测量A0纯铝在去离子水中的极化曲线用来模拟反应堆池壳的点蚀.研究表明A0纯铝在去离子水中很容易钝化.实验中用美国EG&G普林斯顿应用研究公司生产的273型恒电位/恒电流仪测量模拟孔电位,极化曲线表明模拟腐蚀坑处于钝化状态,即便是氧化膜破裂,腐蚀坑也发展得很慢.用pH计测量孔中pH的变化,并得到其工作曲线,此曲线表明带有氧化膜的点蚀坑坑内存在明显的酸化现象.并对A0铝池壳的服务寿命进行了估计.     

Fe替代Co对AB5型贮氢合金循环稳定性的影响

用铸造及快淬的方法制备了稀土基AB5型Mm（NiMnSiAl）4．3Co0.6-xFex（x=0，0．1，0．2，0．3，0．4，0．5，0．6）贮氢合金，用XRD。TEM及SEM观测了铸态及快淬态的微观结构，测试了合金在铸态及快淬态下的电化学循环稳定性。研究了Fe替代Co对铸态及快淬态贮氢合金微观结构及循环稳定性的影响。研究结果表明，Fe替代Co对铸态及快淬态合金的相结构没有明显影响，但对合金的循环稳定性产生显著影响。Fe替代Co能不同程度地改善铸态及快淬态合金的循环稳定性，但对快淬态合金循环寿命的改善更加显著，导致这一结果的主要原因是Fe替代Co使快淬态合金的微观组织显著细化。     

锡磷青铜合金水平连铸工艺参数的优化

铸造锡磷青铜合金组织中存在显微缩松、枝晶偏析和反偏析是冷加工报废的主要原因.通过连铸工艺参数的正交实验,建立了轧制成材率与主要工艺参数之间的神经网络描述,网络模型与遗传算法结合对工艺参数的组合进行了优化,改善了铸坯的组织,提高了轧制带材成材率.     

Influence of expandable graphite on fire resistance and water resistance of flame-retardant coatings

Expandable graphite (EG) coating and ammonium polyphosphate-pentaerythritol-melamine (APP-PER-MEL) coating were prepared. Thermal degradation and char formation of the coatings were investigated by differential thermal analysis (DTA), thermogravimetry (TG), X-ray diffraction (XRD), scanning electron microscopy (SEM) and X-ray photoelectron spectroscopy (XPS). The results have shown that the anti-oxidation and fire-resistant properties of expandable graphite coating containing EG with size of 74 μm are better than those of APP-PER-MEL coating. The static immersion test was applied to study water resistance of the coatings, and the fire protection test and mechanical test were used to analyse heat insulation and mechanical properties of coatings before and after water immersion. The fire-resistant and mechanical properties of APP-PER-MEL coating were severely damaged by water immersion, whereas EG coating containing 8.5% EG with size of 74 μm could retain the good fire resistance even after 500 h water immersion.