Si-N-C 陶瓷的组成、结构与其热稳定性…

本文研究了由聚硅氮烷(PSZ)和聚碳硅烷(PC)热解制得的三种陶瓷的组成、结构与特性。研究表明,PC热解到1250℃产生Si-C陶瓷,其结晶相是β-SiC微晶,PSZ在N_2或NH_3气氛中热解则分别产生Si-N-C与Si-N无定形陶瓷。这三种陶瓷在Ar_2气中1300℃到1500℃处理以研究其热稳定性。结果证明Si-c陶瓷从微晶变为β-SiC结晶态,Si-N陶瓷从无定形态变为α-Si_3N_4结晶并伴随着可观测到的重量损失而Si-N-C陶瓷维持其元素组成及β-SiC微晶态直到1500℃。     

A comprehensive review on material selection for polymer matrix composites subjected to impact load

Polymer matrix composites (PMC) are extensively been used in many engineering applications. Various natural fibers have emerged as potential replacements to synthetic fibers as reinforcing materials composites owing to their fairly better mechanical properties, low cost, environment friendliness and biodegradability. Selection of appropriate constituents of composites for a particular application is a tedious task for a designer/engineer. Impact loading has emerged as the serious threat for the composites used in structural or secondary structural application and demands the usage of appropriate fiber and matrix combination to enhance the energy absorption and mitigate the failure. The objective of the present review is to explore the composite with various fiber and matrix combination used for impact applications, identify the gap in the literature and suggest the potential naturally available fiber and matrix combination of composites for future work in the field of impact loading. The novelty of the present study lies in exploring the combination of naturally available fiber and matrix combination which can help in better energy absorption and mitigate the failure when subjected to impact loading. In addition, the application of multi attributes decision making (MADM) tools is demonstrated for selection of fiber and matrix materials which can serve as a benchmark study for the researchers in future.     

连续碳化硅纤维热交联工艺研究

采用热交联工艺改进传统的空气不熔化工艺,在尽可能少引入氧的情况下实现聚碳硅烷纤维的不熔化处理,降低连续SiC纤维中的氧含量。通过IR、元素分析、SEM、XRD等手段系统研究了热交联工艺条件对纤维氧含量、结构、性能的影响。     

Effect of silicon carbide and wire-mesh reinforcements in dissimilar grade aluminium explosive clad composites

Aluminium composites are inevitable in the manufacture of aircraft structural elements owing to less weight, superior corrosion resistance and higher specific properties. These composites reduce the weight of the aircraft, improve the fuel efficiency and enhance the maintenance duration. This study proposes the development of dissimilar grade aluminium (aluminium 1100-aluminium 5052) composites with different reinforcement’s viz., stainless steel wire-mesh, silicon carbide (SiC) powders and SiC powder interspersed wire-mesh, by explosive cladding technique. Wire-mesh enhances the friction and restricts the movement of flyer plate to craft a defect free clad, while SiC particles form a band on the interface. Highest strength is obtained when SiC powder interspersed wire mesh is employed as reinforcement. The dissimilar aluminium explosive clad with SiC particle reinforcement results in lower strength, which is higher than that of the weaker parent alloy and that of the conventional dissimilar aluminium explosive clads without any reinforcement.     

石墨烯作为水基半合成切削液添加剂的硬质合金-钢材料摩擦学特性分析

改善加工过程润滑条件是延缓刀具磨损的重要途径。将石墨烯作为3034水基半合成切削液的添加剂,研究石墨烯悬浮切削液的硬质合金-钢材料摩擦学性能,研究对象是由硬质合金YG8制备的金属球和由45#钢制备的圆盘形试件;采用球-盘摩擦副接触方式在摩擦磨损试验机上进行试验,测定了质量分数为0. 1%~0. 9%的石墨烯悬浮切削液的平均摩擦特性和摩擦系数;采用激光共聚焦显微镜对磨痕轮廓进行提取,并得出磨损定量评价指数,并用扫描电镜和拉曼光谱仪对磨痕进行磨损机理分析;进行切削实验来分析石墨烯悬浮切削液对切削性能指标的改善情况。实验分析结果表明:石墨烯悬浮切削液能明显改善硬质合金-45#钢之间的润滑条件,摩擦系数和磨损率显著下降,采用不同质量分数石墨烯悬浮切削液的平均摩擦系数较原半合成切削液下降12. 9%~57. 3%,磨损率下降33. 82%,同时切削合力较原半合成切削液下降18. 58%,加工后工件表面粗糙度下降7. 5%。     

聚铝碳硅烷的流变性和纺丝性研究

采用单孔纺丝装置对不同铝含量的聚铝碳硅烷(PACS)的流变性和流变性进行研究.结果表明:随着温度升高,PACS熔体的流体特性逐渐接近牛顿流体;PACS熔体粘度对温度有强烈的依赖性,其软化点在190℃～220℃范围时,其粘流活化能在190～260kJ/mol之间;当PACS的粘度在100Pa·s左右时可纺性好;铝含量对PACS的流变性能和可纺性有重要的影响,随着铝含量的增加,PACS熔体的粘度增大,因而PACS的纺丝温度更高,可纺性变差.     

溶胶凝胶法制备碳化硅陶瓷的影响因素

采用溶胶凝胶法 ,以正硅酸乙酯和酚醛树脂为原料 ,在草酸催化作用下 ,制备出了不含硫和氯的均相碳化硅先驱体 ,并在一定的升温制度下制备出SiC陶瓷。考察了温度对预水解过程的影响以及水用量、催化剂和镍盐用量等因素对凝胶时间的影响。结果表明 ,在预水解温度控制在 4 0℃左右 ,时间为 2 4h时效果最佳 ;而当水与正硅酸乙酯的摩尔比达到 0 2 8左右、草酸与正硅酸乙酯的摩尔比为 0 0 1左右时 ,可以使凝胶时间达到最短。进一步的研究表明 ,镍盐的加入对凝胶烧成过程中 β -SiC的生成有催化作用。     

三维石英纤维增强氮化物基复合材料的烧蚀性能及显微结构

采用先驱体转化法制备了三维石英纤维增强氮化物基复合材料(3D SiO2f/Si3N4-BN),用等离子射流烧蚀方法研究了复合材料的烧蚀性能,运用扫描电镜及能谱仪对烧蚀表面微观形貌进行了观察和分析。结果表明氮化物基复合材料在高压高热流等离子体烧蚀下线烧蚀率为0.91mm/s,石英纤维熔融并被吹除带走了大量的热量,熔融层抑制了基体的机械剥蚀。基体由于强度高、升华温度高,延缓了熔融层的吹除,表明氮化物基复合材料是一种良好的耐高温烧蚀透波材料。     

先驱体转化致密碳化硅纳米复合材料的制备及其热电性能

以聚碳硅烷和锑改性聚硅烷为先驱体,利用先驱体转化Si C材料的富余自由碳高温石墨化的微观结构演变特点,采用热压烧结、先驱体浸渍-裂解法以及退火工艺制备出先驱体转化Si C纳米复合材料。采用SEM、TEM、XRD和Raman等测试手段表征和分析了相组成和微观结构,讨论了样品的热导率、电导率和塞贝克系数等热电参数随温度变化关系。研究表明,所得致密Si C纳米复合材料为n型热电材料。由于纳米石墨的作用,材料热导率抑制在4~8W/(m·K)范围。1600℃退火处理能够降低热导率,同时提高电导率和塞贝克系数绝对值,使先驱体转化法得到的Si C纳米复合材料无量纲热电优值ZT达到0.0028(650℃),高于其他已报道的致密Si C/C复合材料和纳米复合材料体系。     

碳化硼表面金属化初步研究

为了降低碳化硼(B,C)与金属钎焊连接的温度,采用真空熔结Al基钎料的方法,在1000℃时对其进行了表面金属化处理,SEM和EDAX观察分析B4C与钎料结合断面的形貌和元素面分布,发现B4C与钎料界面发生了互扩散,界面结合致密,形成冶金结合.