防锈铝表面喷丸强化冲击试验研究

采用仪器化（数字化）冲击试验机，对防锈铝表面喷丸强化后进行冲击试验，试验结果表明：喷丸后的最大冲击力比母材提高35％，最大力前弹塑性变形功提高166％。     

Microstructure development of steel during severe plastic deformation

The microstructure development during plastic deformation was reviewed for iron and steel which were subjected to cold rolling or mechanical milling (MM) treatment, and the change in strengthening mechanism caused by the severe plastic deformation (SPD) was also discussed in terms of ultra grain refinement behavior. The microstructure of cold-rolled iron is characterized by a typical dislocation cell structure, where the strength can be explained by dislocation strengthening. It was confirmed that the increase in dislocation density by cold working is limited at 10¹⁶m⁻², which means the maximum hardness obtained by dislocation strengthening is HV3.7 GPa. However, the iron is abnormally work-hardened over the maximum dislocation strengthening by SPD of MM because of the ultra grain refinement caused by the SPD. In addition, impurity of carbon plays an important role in such grain refinement: the carbon addition leads to the formation of nano-crystallized structure in iron.     

ANALYSIS ON THE BEHAVIOR OF PRECIPITATES IN ULTRA-THIN HOT STRIP OF PLAIN LOW CARBON STEEL PRODUCED BY COMPACT STRIP PRODUCTION

This paper investigated the mechanism of precipitation and its influence upon prop-erties of ultra-thin hot strips of low carbon steel produced by CSP techniques using experiment and thermodynamics theory. The experimental results show that there are lots of fine and dispersive precipitates in microstructures. By analysis, most of aluminum nitrides are in grains, while coexisted precipitates of MnS are along grain boundaries. Coexisted precipitates compose cation-vacancy type oxides such as Al2O3 in the core, while MnS is at the fringe of surface. The precipitation behavior of AlN and MnS in the hot strip is studied by thermodynamic calculation. At last, implica-tions between strengthening effect and techniques are analyzed using obtained solubility products.     

新型自润滑YBa_2Cu_3O_7/Cu复合材料的制备及性能

采用草酸盐共沉淀法制备了YBa2Cu3O7(YBCO)粉体,利用真空热压烧结法制备了不同质量分数的YBCO/Cu复合材料,测定了YBCO/Cu复合材料的密度、硬度和电导率,利用MMU-5GA磨损试验机对YBCO/Cu复合材料进行了摩擦磨损试验。采用XRD、SEM和TEM对YBCO粉体及YBCO/Cu复合材料的微观结构、磨损表面形貌及物相组成进行了表征。研究了YBCO质量分数对YBCO/Cu复合材料组织及性能的影响。结果表明:所制备的YBCO粉体物相为Y123相,其层状结构明显,粉体纯度高、杂质少,粒度达到纳米级;纳米YBCO可显著细化YBCO/Cu复合材料的基体组织,提高复合材料的摩擦学性能。随着YBCO质量分数增加,基体组织中纳米YBCO颗粒分布均匀度降低,逐渐出现团聚;YBCO/Cu复合材料的电导率和密度降低,硬度先升高后降低,摩擦系数逐渐减小。3%YBCO/Cu复合材料的摩擦磨损性能最好。YBCO/Cu复合材料强化机制为Orowan强化、热错配强化和细晶强化;其磨损机制主要为塑变磨损、磨粒磨损和疲劳剥落。     

石墨烯增强金属基复合材料的研究进展

石墨烯由于独特的结构和优异的性能已成为金属基复合材料中最具吸引力的碳质材料增强体。综述了近年来石墨烯增强金属基复合材料的研究进展、强化机制及石墨烯表面改性进展,分析了石墨烯增强金属基复合材料研究存在的问题,并对石墨烯增强金属基复合材料的研究方向及发展趋势进行了展望。     

Mg-Nd-Y-Zr合金的无熔剂保护制备工艺研究

以金属镁、金属钕、镁钇中间合金和镁锆中间合金为原料,进行Mg-Nd-Y-Zr合金的无熔剂制备工艺的研究。通过考察熔炼温度、熔炼时间、合金液静置时间以及浇铸温度等工艺参数对合金收率、合金元素收率以及合金元素偏析程度等技术指标的影响,结合对合金铸态组织结构的研究,确定Mg-Nd-Y-Zr合金的均质纯净化制备工艺条件为:熔炼温度770℃、熔炼时间150 min、物料加入速率50 g/min、保护气中SF6体积分数0.1%、合金液静置时间60 min以及浇铸温度740℃。该工艺条件下,合金收率大于96%,合金元素偏析程度为±(0.05~0.15)%(质量分数),合金元素含量偏差±(0.03~0.10)%(质量分数),合金内部无氧化缺陷,无杂质元素的引入富集。合金中的典型强化相为Mg41Nd5、Mg12Nd及Mg2Y相,呈网状分布,钕和钇元素对合金具有弥散强化作用;锆元素在合金中具有晶粒细化和铁杂质去除的双重作用。     

Reinforcement in Al Matrix Composites: A Review of Strengthening Behavior of Nano‐Sized Particles

Aluminum matrix composites (AMCs) reinforced with the nano‐sized particles are very important materials for the applications in industrial fields. These aluminum matrix composites consist of an aluminum matrix and nano‐sized particles, which own very different physical and mechanical properties from those of the matrix. Nano‐sized particles show a more obvious strengthening effect on the matrix than the micro‐sized particles do, because of the high specific surface area which is positive for the pinning effect during the deformation process. Thus, the nano‐sized particle‐reinforced AMCs usually exhibit a good ductility. The main issues of the fabrication methods are the low wettability between the nano‐sized particles and the molten aluminum alloys, which is fatal to the conventional casting methods, and the agglomeration of nano‐sized particles which happened easier than the larger particles. Several alternative processes have been presented in literature for the production of the nano‐sized particle‐reinforced aluminum composites. This paper is aimed at reviewing the feasible manufacturing techniques used for the fabrication of nano‐sized particle‐reinforced aluminum composites. More importantly, the strengthening mechanisms and models which are responsible for the improvement of mechanical properties of the nano‐sized particle‐reinforced aluminum composites have been reviewed.

     

微量Mg元素添加对Cu-Cr合金析出行为及性能的影响

通过熔炼铸造工艺制备了Cu-Cr和Cu-Cr-Mg合金,评价了Mg元素对Cu-Cr合金硬度、导电和抗软化性能的影响,研究了Mg元素对Cu-Cr合金析出相的细化作用,探讨了Mg元素的迁移行为。结果表明,相比于Cu-Cr二元合金,时效态Cu-Cr-Mg合金具有更高的硬度和软化温度,且保持较高的导电性能。两种合金的主要时效强化相均为纳米Cr析出相,Mg元素的加入抑制了纳米沉淀相的长大和结构转变,峰时效态Cu-Cr-Mg合金的析出相与基体可能仍保持共格界面关系,过时效态合金中出现与Heulser相结构相同的析出相,且峰时效态Cu-Cr-Mg合金经过高温保温处理后,其强化相的尺寸明显小于Cu-Cr合金析出相。EDS的结果表明,在时效初期Mg和Cr共存于析出相内部,而在时效后期析出相内部只有Cr元素存在,Mg元素发生迁移,同时理论估算结果显示,Mg元素可明显降低Cu(fcc)/Cr(bcc)之间的界面能,导致其偏聚于基体/析出相界面处,这可能是Mg元素能够细化析出相和提高合金性能的主要原因。     

纳米碳酸钙粒子增韧增强不饱和树脂的研究

报道了纳米级碳酸钙填充不饱和树脂的性能研究，探讨了碳酸钙含量和钛酸酯偶联处理对不饱和树脂性能的影响，用扫描电镜（SEM）观察了试样的断裂口形貌，结果表明，用偶联剂处理的纳米碳酸钙粒子含量在4份左右时对复合材料的综合性能最佳，比未加纳米粒子的和未处理的材料冲击强度分别提高了370％和170％，拉伸强度分别提高了170％和150％，SEM分析说明未处理粒子增韧不饱和树脂的机理是粒子的“钉扎”效应和钝化裂纹，而偶联剂处理的纳米粒子增韧不饱和树脂的机理主要是料子导致基体产生了塑性变形。     

加固用复合材料力学性能的影响因素

在土木工程中，混凝土结构的加固补强要求连续纤维增强树脂基复合材料应具有较高的抗拉强度、弹性模量和一定的断裂延伸率，本文探讨了在一定成型工艺和环氧树脂基体的条件下，影响这些性能的因素．试验表明，纤维品种、纤维表面处理方法、片材厚度对这些性能有显著的影响；纤维束或纤维布与树脂基体复合固化后，由于固化应力的作用，其增强效率将大大下降。对此，在加固设计时应予以重视。