Effect of Alumina Particles Addition on Physico-Mechanical Properties of AL-Matrix Composites

Metal-matrix composites (MMCs) are attracting considerable interest worldwide because of their superior mechanical and tribological properties. This study describes multifactor-based experiments that were applied to research and investigates Aluminum matrix composite reinforced with 5, 10 & 15 wt% Alumina particles. Mechanical mixing technique was used for fabrication. Sintering was carried out in a vacuum furnace at 600°C for 1 hr. The effects of Alumina percentage on the density, microstructure, both electrical & thermal conductivities, hardness and compression strength was investigated. The results showed that sample containing 5 wt% Alumina is near-fully dense. Also it has the highest hardness and compression strength.

Microstructure and Tensile Properties of Yttria Coated-Alumina Particulates Reinforced Aluminum Matrix Composites

The liquid-phase coating method was used to deposit Y2O3 ceramic on the surface of α-Al2O3. The coated-Al2O3p/6061AI composites were produced using squeeze casting technology. The microstructure and tensile properties of the composites were analysed and studied. The results showed that the coated AI2O3 particles are able to disperse homogeneously in the aluminum liquid. The microstructure of the composites is more even in comparison with that of as-received powders. The tensile testing indicated that mechanical properties of the coated-AI2O3p/6061AI composites are better than those of uncoated particles. In the composite with 30% volume fraction, the tensile strength, yield strength as well as elongation is increased by 29.8%, 38.4% and 10.3%, respectively. The SEM analysis of fracture indicated that the dimples of the coated-Al2O3p/6061Al composites are more even.

Elaboration and characterization of alumina - fluorapatite composites

Alumina and fluorapatite powder were mixed in a wet medium in order to elaborate biphasic ceramics composites. The effect of fluorapatite addition (26.5 wt%) in the densification and the mechanical properties of the alumina matrix were measured. The phase developments have been systematically analysed by scanning electronic microscopy, X-ray diffraction, Infrared spectroscopy and 31P and 27Al magic angle scanning nuclear magnetic resonance. The Brazilian test was used to measure the mechanical resistance of alumina - 26.5 wt% fluorapatite composites. The densification and strength rupture of composites increase versus sintering temperature and holding time. At 1600°C, the composites densities reached 85% and the rupture strength was about 22 MPa. Also, the composites sintering at 1500°C for 5 hours provides samples with similar density and having higher mechanical resistance, above 26 MPa. For longer holding times, the mechanical properties were hindered by the exaggerated grain growth and the formation of intragranular porosity. From 1400°C, the characterization of the alumina - 26.5 wt% fluorapatite composites indicates the formation of calcium aluminates.

Large Scale Analysis of Mechanical Properties in 3-D Fiber-Reinforced Composites Using a New Fast Multipole Boundary Element Method

Fiber-reinforced composites are commonly used in various engineering applications. The mechanical properties of such composites depend strongly on micro-structural parameters. This paper presents a new boundary element method （BEM） for numerical analysis of the mechanical properties of 3-D fiberreinforced composites. Acceleration of the BEM is achieved by means of a fast multipole method （FMM）, in allowing large scale simulations of a finite elastic domain containing up to 100 elastic fibers to be performed on one personal computer. The maximum number of degrees of freedom can reach a value of over 250 000. The effects of several key micro-structural parameters on the local stress fields and on the effective elastic moduli of fiber-reinforced composites are evaluated. The numerical results are compared with analytical predictions and good agreement is observed. The results show that the fast multipole BEM could be a promising tool for further understanding of the mechanical behavior of such composites.

Microstructure and mechanical properties of Al-B4C composite at elevated temperature strengthened with in situ Al2O3 network

This study evaluated the mechanical properties and thermal properties of Al-12 vol%B4 C composite at elevated temperature strengthened with in situ Al2 O3 network.The composite was fabricated using powder metallurgy(PM)with raw materials of fine atomized aluminum powders,and the associated microstructures were observed.At 350℃,the composite had ultimate tensile strength of UTS=137 MPa,yield strength of YS0.2=118 MPa,and elongation ofε=4%.Besides,the mechanical properties of the composite remained unchanged at 350℃after the long holding periods up to 1000 h.The excellent mechanical properties and thermal stability at 350℃were secured by in situ am-Al2O3 network that strengthened the grain boundaries.The interfacial debonding and brittle cracking of B4 C particles were the main fracture mechanisms of the composite.In addition,the influence of sintering temperature and rolling deformation on the microstructures and mechanical properties was studied.

Y2O3对Micro-FAST制备铜基复合材料组织与性能的影响

采用多物理场活化烧结微成形技术(Micro-FAST)制备了Y2O3/Cu复合材料。对复合材料的相对密度、硬度、电导率进行了测试并对其显微组织进行了观察,研究了增强相Y2O3的添加量对复合材料组织及性能的影响。结果表明,随着Y2O3含量的增加,复合材料的相对密度、硬度及电导率均表现出先增加后降低的趋势,且各性能均在添加的Y2O3质量分数为1.0%时达到峰值。其中,相对密度高达99.91%,显微硬度及电导率分别达到75.8 HV和50.26 MS/m,复合材料的综合性能达到最优。Y2O3/Cu复合材料的各项性能均明显优于纯铜烧结试样,Y2O3增强相的作用明显。

低共熔溶剂预处理对表面矿化木材性能的影响

【目的】为了解决木材矿化改性渗透难、矿化位点少等问题,本研究采用低共熔溶剂(DES)预处理速生杨木、打开木材渗透通道、构建活性位点,研究低共熔溶剂预处理对表面矿化木材性能的影响。【方法】本研究使用DES预处理杨木构建矿化位点,诱导SiO_(2)在木材表面实现原位矿化,再通过热压制备表面矿化木材,分析DES预处理对表面矿化木材物理力学性能的影响作用;以较优条件制备表面矿化木材,并分析其微观结构形貌和热性能。【结果】(1)表面矿化木材的密度、质量增长率和表面硬度均随DES预处理时间的增加呈先上升后下降的趋势;预处理为2 h时,较未处理材分别提高了35.25%、16.35%和51.53%;表面矿化木材的疏水性大幅提高,预处理0.5 h时初始接触角增大了74.08%。(2)DES预处理可以显著改善表面矿化木材力学性能;当DES预处理时间为2 h时,表面矿化木材的抗弯强度和弹性模量分别提升了20.53%和214.55%。(3)表面矿化处理向木材内引入SiO2形成有机–无机杂化结构,提高木材阻燃性能;DES预处理2 h时,表面矿化木材的质量残余率相较于未处理材提高了70.81%,热释放速率降低了69.9 kW/m^(2),总热释放量降低了27.3 MJ/m^(2)。【结论】速生杨木经DES预处理和表面矿化联合改性后物理力学性能提升,热稳定性和阻燃性能良好。

回收聚丙烯纳米复合材料的性能

采用硅烷偶联剂和硬脂酸对纳米二氧化硅(nano-SiO2)进行了复合改性,再通过双螺杆挤出机熔融共混制备了回收聚丙烯(RPP)纳米复合材料。研究表明,改性nano-SiO2有良好的疏水亲油性能和良好的分散效果。随着改性nano-SiO2质量分数的增加,RPP纳米复合材料的熔体质量流动速率先增大后减小,当改性nano-SiO2的质量分数为1%时,复合材料的熔体质量流动速率达到最大值。当改性nano-SiO2的质量分数仅为0.5%时,RPP复合材料的缺口冲击强度达到最大值22.23 kJ/m^(2),比0.5%未改性nano-SiO2/RPP的缺口冲击强度提高了134.99%。随着改性nano-SiO2质量分数的不断增加,复合材料的拉伸强度呈先增大后下降的趋势,3%改性nano-SiO2/RPP的拉伸强度达到最大值20.6 MPa。当红磷(RP)的质量分数为20%,改性nanoSiO2的质量分数为2%和3%时,RPP复合材料的阻燃级别达到UL94 V-0级。通过研究改性nano-SiO2对RPP的结构和性能的影响,为回收聚烯烃材料的高质化再生利用提供了价值参考。

不同熔剂体系制备的陶瓷岩板及其性能

本文利用钾钠质与钙镁质原料配制了SiO_(2)-Al_(2)O_(3)-K_(2)O(Na_(2)O)(K_(2)O-Na_(2)O)与SiO_(2)-Al_(2)O_(3)-CaO-MgO(CaO-MgO)体系陶瓷,系统探究了熔剂体系(CaO-MgO、K_(2)O-Na_(2)O)在不同烧结温度(1 110~1 210℃)下对陶瓷岩板烧结性能和力学性能的影响,并利用XRD和SEM研究陶瓷岩板的物相组成和显微结构演变规律。结果表明:CaO-MgO与K_(2)O-Na_(2)O体系陶瓷的最佳烧结温度分别为1 170、1 150℃,钙镁质原料的引入导致CaO-MgO体系陶瓷的烧成收缩率与体积密度均低于K_(2)O-Na_(2)O体系陶瓷,且CaO-MgO体系陶瓷中气孔尺寸与含量均大于K_(2)O-Na_(2)O体系陶瓷;钙镁质原料的引入会促进CaO-MgO体系陶瓷中钙长石与α-堇青石的形成,且可以大幅度提升CaO-MgO体系的结晶相含量(质量分数为75.66%,较K_(2)O-Na_(2)O体系高56%)。高结晶相含量导致的弥散强化效果大于气孔对强度的劣化作用,CaO-MgO体系的弯曲强度为(56.9±2.6) MPa、断裂功为(183.2±9.5) J/m^(2)、极限应变为(7.4±0.1)×10^(-4)、比强度为(24.9±1.1) kN·m·kg^(-1),较K_(2)O-Na_(2)O体系分别提高了15%、25%、11%、23%,这说明CaO-MgO熔剂体系陶瓷更加适用于高强韧、高柔性陶瓷岩板的制备。

氧化铝复合陶瓷烧结工艺研究与力学性能改善

研究了反应结合Al2O3－ZrO2－SiC复合陶瓷的烧结工艺与力学性能改善途径，对快速烧结与Ar气氛常压烧结工艺及材料力学性能进行对比，并分析了微观结构．实验结果表明，快速烧结是抑制晶粒生长、获得均匀、细微、致密结构的有效途径，材料的力学性能也达到了较好水平，但其工艺难度大，而Ar气氛常压烧结工艺简便易行，也可获得相当水平的力学性能．经热等静压使材料充分致密化，消除缺陷，力学性能大幅度提高．

SiO_2/CrO_3对SHS陶瓷复合钢管力学性能的影响

采用重力分离自蔓延高温合成技术，制备了陶瓷内衬复合钢管，研究了添加ＣｒＯ３和ＳｉＯ２对陶瓷复合钢管的压溃强度、压剪强度、陶瓷层相对密度、显微硬度的影响．结果表明：添加ＳｉＯ２可以通过增加低熔点相来提高复合钢管的力学性能，以ＣｒＯ３部分取代Ｆｅ２Ｏ３可以通过升高反应温度来提高复合钢管的力学性能．同时加入４％ＳｉＯ２（质量分数，下同）和８％ＣｒＯ３，可以获得性能优良的陶瓷内衬复合钢管．

氢氧化镁粒径对其填充三元乙丙橡胶复合材料力学性能和阻燃性能的影响

分别以粒径为 1 0 0nm ,6 2 9,3 5 7,2 92 μm的氢氧化镁为阻燃剂和增强剂 ,加入到 1 0 0份 (质量 )三元乙丙橡胶中 ,考察了填料粒径对复合材料力学性能和阻燃性能的影响。结果表明 ,随着氢氧化镁粒径的减小 ,复合材料的力学性能逐渐提高 ,纳米复合材料的力学性能远优于微米复合材料的。采用锥形量热仪和氧指数仪研究了复合材料的阻燃性能 ,发现对于未改性氢氧化镁填充体系 ,随着粒径的减小 ,复合材料的最大热释放速率降低 ,引燃时间增长。氢氧化镁经过硅烷偶联剂 (Si 69)改性后 ,纳米复合材料的力学性能显著提高 ,最大热释放速率和引燃时间变化不大 ;而微米复合体系的力学性能和阻燃性能都无明显变化。

常压烧结制备Al_2O_3/TiCN复合陶瓷材料

采用常压烧结的方法制备Al_2O_3/TiCN复合陶瓷,研究了试样成分、烧结温度对试样相对密度、抗弯强度、断裂韧性、Vickers硬度等力学性能的影响。结果表明:采用Al_2O_3+TiCN作为埋粉、氩气保护、在烧结温度低于1650℃,保温时间为1h时,烧结试样的相对密度最高为98.0％,其抗弯强度、断裂韧性、及硬度分别达到最大值,为851 MPa,5.94 MPa·m^(1/2),21.12 MPa。显微结构分析表明:TiCN颗粒弥散在Al_2O_3晶界处,晶粒细小,多在1 μm左右,分布均匀,TiCN与Al_2O_3颗粒相互交织在一起,抑制晶粒生长,从而起到了增韧补强作用,有利于材料力学性能的提高。从压痕裂纹尖端的扩展的扫描电镜照片可以看出:基体与增强相多个晶粒构成的裂纹桥联行为;而有的则在其初始或(和)末端与其他次主裂纹相互作用,形成裂纹偏转、分支与桥联的共存区,主要起作用的是TiCN颗粒弥散增韧机制,它将纯Al_2O_3陶瓷的断裂韧度从3.59 MPa·m^(1/2)提高到5.94 MPa·m^(1/2)。

APP对木粉-HDPE复合材料阻燃和力学性能的影响

以聚磷酸铵(APP)对木粉-HDPE复合材料(WF-HDPE)进行阻燃处理,用锥形量热仪系统评价复合材料的阻燃性能,并进行等温燃烧反应动力学分析,用万能力学试验机进行静态力学试验。结果表明,在35 kW/m2热辐射流量下,APP添加量达到15%时,WF-HDPE燃烧热释放速率(RHR)峰值和总热释放量(THR)均降低约50%、成炭率提高150%,表现出显著的阻燃作用;可用动力学模型ln(1-α)=-kt+C描述WF-HDPE的等温燃烧反应,APP的加入使反应速率常数k降低、半衰期延长。APP对WF-HDPE的冲击性能有显著的不利影响,但能改善刚性,对弯曲强度和拉伸强度影响不大。综合阻燃性能与力学实验结果,APP的适宜添加量为15%左右。

表面改性处理对氧化铝/环氧树脂复合材料力学性能的影响(英文)

对未改性和表面偶联处理的氧化铝颗粒填充环氧树脂复合材料(颗粒体积分数为20%,35%和40%)的力学性能进行对比研究。通过对改性前后复合材料结构的均匀性和抗拉伸性能的分析得出以下结论:添加了偶联处理后的氧化铝颗粒使复合材料的均匀性、断裂强度和弹性模量都有了较大程度的提高。原因在于对颗粒的表面偶联改性处理使颗粒间存在的黏聚吸附力下降,增加了颗粒与树脂基体间的结合力,使氧化铝颗粒能够在树脂基体中达到很好的分散状态。采用扫描电镜分析手段对样品断口形貌的分析说明材料内部界面间的结合状态以及颗粒在基体中的分布状况。

改性处理对杨木力学和燃烧性能的影响

采用硼酸复配酚醛树脂(简称BPF)对速生杨木进行改性,研究了改性处理对杨木力学和燃烧性能的影响,并与杉木和花旗松进行了对比.结果表明,杨木未达到规范中最低一级的强度等级,20%,BPF改性材强度等级达到TB11级,30%,BPF和40%,BPF改性材达到TB13级;20%,BPF、30%,BPF和40%,BPF改性后,试件氧指数分别提高97.37%,、113.68%,和128.42%,;与花旗松和杉木相比,杨木热释放速率、总热释放量和CO_2生成速率更高,BPF改性处理能有效地降低杨木可燃性,延长杨木的点燃时间,且改性程度越高,阻燃效果越好,其中40%,BPF改性后,试件总热释放量峰值降低31.22%,,比花旗松高14.33%,;总热释放量与花旗松持平,CO_2生成速率峰值降低30.57%,,比花旗松高6.01%,,残重率提高64.83%,,燃烧性能已达到常规建筑用材的水平.

Al_2O_3/Steel-epoxy层状复合材料的制备和性能

采用环氧树脂胶黏剂作为粘结剂,通过一种简单的模压方法,在5 MPa压力下常温固化,制备了一系列Al2O3/steel-epoxy层状复合陶瓷材料。结果显示,Al2O3/epoxy界面和steel/epoxy界面结合紧密。相比于氧化铝薄片,Al2O3/steel-epoxy层状复合陶瓷材料强度差别不大,但具有更高的断裂韧性、冲击韧性和断裂吸收能。裂纹扩展分析认为层状复合材料断裂韧性和能量吸收的提高主要得益于裂纹尖端钝化和捕获、裂纹桥连、层间脱粘和steel-epoxy层的塑性变形等机制。

Al_2O_3/ZrB_2/ZrO_2复合陶瓷材料的制备与性能

将ZrB2和ZrO2添加入到Al2O3基体中,采用热压法制备了Al2O3/ZrB2/ZrO2复合陶瓷材料,ZrB2和ZrO2的体积含量分别为(92.2±0.1)%和(7.8±0.1)%。对复合材料的硬度、断裂韧性和抗弯强度进行了测试和分析。结果表明:当ZrB2/ZrO2体积分数为20%时,所制备的复合陶瓷的综合力学性能最优,其相对密度,抗弯强度和断裂韧度分别达到96.3%,520.5MPa和6.1MPa.m1/2。Al2O3/ZrB2/ZrO2复合陶瓷断面的断裂模式为沿晶断裂和穿晶断裂混合模式。通过高温氧化试验发现Al2O3/ZrB2/ZrO2复合材料在500～700℃时开始氧化。

可加工性BN/Al_2O_3陶瓷基复合材料的制备

利用气相化学反应 ,以H3 BO3 和CO(NH2 ) 2 作为BN源 ,将纳米BN包覆到Al2 O3 颗粒表面 ,经热压烧结制备出高强韧可加工BN/Al2 O3 复合材料。材料的三点弯曲强度随BN含量的增加而缓慢降低 ,BN体积分数为30 %时 ,仍达到 44 6MPa;断裂韧性随BN含量的增加而得到显著改善 ,较单相氧化铝陶瓷提高近一倍。BN体积分数大于 2 0 %时 ,该复合材料可用WC钻头在普通台式钻床上钻孔 ,在小的轴向压力 (10N)下 ,钻孔速率大于 1mm/min ,钻孔边缘平整 ,没有崩裂现象 ,内壁光滑 ,粗糙度RZ=(6± 0 .5 ) μm。SEM观察显示 ,加工未带来明显的损伤。材料优异的力学性能及可加工性源自于基质中均匀分布的细小h BN的颗粒增韧机制及其易解理的层状结构特点。