Al_(2)O_(3)/SiO_(2)混合纳米流体微量润滑铣削润滑性能评价

由于不同纳米粒子组成的混合纳米流体比单一纳米粒子切削液具有更好的热物理性能,研究了纯Al_(2)O_(3)、纯SiO_(2)和不同质量比混合纳米流体微量润滑(minimum quantity lubrication,MQL)铣削45号钢的切削性能。试验结果表明,混合纳米流体比纯SiO_(2)铣削力降低,接触角减小,工件微观形貌好。不同配比的混合纳米粒子展现出了不同的润滑效果。当Al_(2)O_(3)的配比小于SiO_(2)时,Al_(2)O_(3)纳米粒子未完全包覆住SiO_(2),润滑效果较差。随着Al_(2)O_(3)比例增加,切削力和接触角都显著减小,工件表面质量提高。当Al_(2)O_(3)和SiO_(2)的质量比为3∶1时,得到的铣削力、表面粗糙度和接触角最小,工件表面质量最好。由此可见,Al_(2)O_(3)的含量影响了混合纳米流体的润滑效果。

原位合成Al_(2)O_(3)/TiB_(2)颗粒混杂增强铝基复合材料的性能研究

针对传统铝合金无法满足工业和民用中对高强高导铝合金需求的问题,开发一种提升铝合金表面硬度且保证其导电导热性能的新型铝基复合材料。通过机械合金化法制备了Al-TiO_(2)-B混合粉末,采用放热弥散结合接触反应技术成功原位合成Al_(2)O_(3)/TiB_(2)颗粒混杂增强铝基复合材料,探究了原始粉末Al-TiO_(2)-B体系反应生成Al_(2)O_(3)/TiB_(2)颗粒混杂增强铝基复合材料的反应机理及反应温度对原位反应的影响,分析了铝基复合材料的微观组织形貌以及表面显微硬度和导电导热性能。XRD分析结果表明,反应温度达到1100℃保温200 min后,原始粉末Al-TiO_(2)-B体系中的TiO_(2)和B粉末完全反应,并且在反应过程中B粉抑制了中间产物Al3Ti和AlB2的生成,最终原位生成为Al_(2)O_(3)和TiB_(2)颗粒混杂增强的铝基复合材料。显微组织观察表明,在铝基体中原位生成了TiB_(2)颗粒(直径小于1μm)和Al_(2)O_(3)颗粒(粒径约为2μm),且铝基复合材料表面组织均匀致密。原位合成Al_(2)O_(3)/TiB_(2)混杂颗粒增强铝基复合材料的电导率为46.1%IACS,热导率约为198.5 W·m-1·K-1,显微硬度较传统A356铝合金的68 HV提升至76 HV,新型原位合成铝基复合材料在保证导电导热性能的前提下提升了铝基复合材料的显微硬度。

Ir-MOx/Al_(2)O_(3)催化剂上硝基芳烃加氢性能研究

采用正丁基锂快速还原法合成了双金属IrM(M=Ni、Fe和Co)纳米颗粒,并以其为前体在氧化铝载体上经过原位煅烧和选择性还原,制得具有明确Ir-MOx杂化界面结构的Ir-MOx/Al_(2)O_(3)催化剂。结果表明,相比Ir/Al_(2)O_(3)催化剂,Ir-MOx/Al_(2)O_(3)在对氯硝基苯和对硝基苯乙酮选择性加氢制备氨基芳烃的反应中均展现了显著的活性和选择性的增强。在所有Ir基催化剂中,Ir-CoOx/Al_(2)O_(3)具有最高的活性和选择性,这归因于Ir和CoOx间的强相互作用力。Ir-CoOx/Al_(2)O_(3)在10余种取代硝基芳烃选择性加氢反应中均展现了高的活性和选择性,展现了广泛的底物普适性。经过5次循环实验,Ir-CoOx/Al_(2)O_(3)的活性和选择性均未发生明显变化,这表明合成的催化剂具有稳定的结构。

Al_(2)O_(3)-Sn_(57)Bi_(43)/环氧树脂复合材料的导热及电性能

在聚合物基体中构建由高导热填料相互连接而成的导热通路是提高复合材料导热性能的有效策略。本文采用共还原法,在Al_(2)O_(3)微球表面沉积低熔点纳米锡铋合金颗粒(Sn_(57)Bi_(43)),制备杂化材料(Al_(2)O_(3)-Sn_(57)Bi_(43)),用于环氧树脂的导热绝缘填料。当环氧树脂受热固化时,Al_(2)O_(3)-Sn_(57)Bi_(43)表面Sn_(57)Bi_(43)纳米颗粒熔融,将填料相互连接而形成有效的导热通路,提高复合体系导热性能。当填料体积含量为60vol%时,Al_(2)O_(3)-Sn_(57)Bi_(43)/环氧树脂复合材料的导热系数为2.95 W·(m·K)^(-1),比Al_(2)O_(3)/环氧树脂复合材料的导热系数(1.82 W·(m·K)^(-1))提高了62.1%。Fogyel及Agari模型分析表明,Al_(2)O_(3)表面沉积Sn_(57)Bi_(43)有利于降低填料间接触热阻,形成导热通路。与Al_(2)O_(3)/环氧树脂复合材料相比,Al_(2)O_(3)-Sn_(57)Bi_(43)/环氧树脂复合材料的介质损耗增加,介电强度及体积电阻率降低,但仍具有电绝缘性能。由于填料-基体间界面性能改善及Al_(2)O_(3)-Sn_(57)Bi_(43)形成的网链结构能起到传递应力,阻止裂纹扩张的作用,Al_(2)O_(3)-Sn_(57)Bi_(43)/环氧树脂复合材料的拉伸断裂强度提高。

Temporal Stability Analysis of Magnetized Hybrid Nanofluid Propagating through an Unsteady Shrinking Sheet: Partial Slip Conditions

The unsteady magnetohydrodynamic(MHD)flow on a horizontal preamble surface with hybrid nanoparticles in the presence of the first order velocity and thermal slip conditions are investigated.Alumina(Al_(2)O_(3))and copper(Cu)are considered as hybrid nanoparticles that have been dispersed in water in order to make hybrid nanofluid(Cu-Al_(2)O_(3)/water).The system of similarity equations is derived from the system of partial differential equations(PDEs)by using variables of similarity,and their solutions are gotten with shooting method in the Maple software.In certain ranges of unsteadiness and magnetic parameters,the presence of dual solutions can be found.Further,it is examined that layer separation is deferred due to the effect of the hybrid nanoparticles.Moreover,the capacity of the thermal enhancement of Cu-Al_(2)O_(3)/water hybrid nanofluid is higher as compared to Al_(2)O_(3)/water based nanofluid and enhancements inCu are caused to rise the fluid temperature in both solutions.In the last,solutions stability analyzes were also carried out and the first solution was found to be stable.