二步煅烧法制备高热稳定性无定形SiO_(2)-Al_(2)O_(3)复合粉体

采用二步煅烧法制备了高热稳定性无定形SiO_(2)-Al_(2)O_(3)复合粉体。首先以十二水合硫酸铝铵和葡萄糖为原料混合煅烧制备无定形Al_(2)O_(3)前驱体,然后以正硅酸乙酯形式向无定形Al_(2)O_(3)中引入适量的SiO_(2),煅烧后即可获得具有高热稳定性的无定形SiO_(2)-Al_(2)O_(3)复合粉体。当SiO_(2)引入量为26%(质量分数)时,粉体经950℃下煅烧4 h仍为无定形结构;对前驱体进行研磨后,粉体热稳定性进一步提升,在1 020℃下煅烧4 h仍为无定形结构。研究表明,SiO_(2)引入量和前驱体混合均匀性对复合粉体的高温热稳定性有明显影响。

Ti_(2)AlC粉末粒径分布对TiC_(0.5)-Al_(2)O_(3)/Cu复合材料组织及性能的影响

通过不同时间的湿法球磨得到不同粒径分布的Ti_(2)AlC粉末,再与Cu_(2)O粉末和铜粉末混合,利用放电等离子烧结技术制备TiC_(0.5)-Al_(2)O_(3)/Cu复合材料,研究了Ti_(2)AlC粉末粒径分布对其组织和性能的影响。结果表明:随着Ti_(2)AlC粉末中亚微米级颗粒体积分数由0增加到70.27%,复合材料中增强相颗粒TiC_(0.5)和Al_(2)O_(3)在基体中分散更均匀,但是当亚微米级颗粒体积分数为98.07%时,增强相颗粒出现聚集现象;随着亚微米级颗粒体积分数的增加,复合材料的导电率与相对密度先减小后增大,硬度与屈服强度则先升后降,当亚微米级颗粒体积分数为70.27%时,复合材料综合性能最优异。

TiO_(2)-Al_(2)O_(3)复合粉体的制备及光催化性能

Al_(2)O_(3)陶瓷膜在过滤染料废水过程中容易被染料大分子堵塞,导致Al_(2)O_(3)陶瓷膜水通量下降。以钛酸丁酯、异丙醇铝为前驱体,采用溶胶-凝胶法制备Ti(OH)_(4)-AlOOH复合溶胶,经450℃烧成获得TiO_(2)-Al_(2)O_(3)复合粉体。以SEM、纳米粒度/电位仪作为主要表征手段,研究了不同Ti(OH)_(4)和AlOOH摩尔比对复合溶胶粒径分布的影响,进而探究TiO_(2)-Al_(2)O_(3)复合粉体的光催化性能。结果表明,Ti(OH)_(4)和AlOOH摩尔比为0~0.4时,随着Ti(OH)_(4)和AlOOH摩尔比的增大,胶粒的平均粒径从67.5 nm减小到34.0 nm, Ti(OH)_(4)-AlOOH复合溶胶的电位从43 mV升高至53 mV。当Ti(OH)_(4)和AlOOH摩尔比为0.4时,复合粉体对结晶紫的去除率高达79.3%,反应速率常数增大到了0.018 min^(-1)。TiO_(2)-Al_(2)O_(3)复合粉体制备的陶瓷膜能有效降解表面沉积的大分子,解决了陶瓷膜堵塞的问题。

液相法制备棒状Al_(2)O_(3)及Al_(2)O_(3)-ZrO_(2)陶瓷复合粉体

采用二乙三胺五乙酸(DTPA)为配合剂,以简易的液相法合成出微纳米纤维状Al和Al-Zr前体,煅烧处理制备了棒状α-Al_(2)O_(3)和Al_(2)O_(3)-ZrO_(2)复合陶瓷粉体。同时研究了DPTA∶Al^(3+)质量比、反应温度与时间对陶瓷粉体形态的影响。利用X射线衍射(XRD)、热分析(TG/DSC)以及扫描电子显微镜(SEM)对粉体进行了表征。结果表明:较高的DTPA∶Al^(3+)质量比以及较长的反应时间有利于制备高长径比的纤维棒状Al和Al-Zr配合物前体。合成纳米纤维状α-Al_(2)O_(3)和Al_(2)O_(3)-ZrO_(2)前体的最优条件是反应温度60℃,反应时间5.5h,DTPA∶Al^(3+)比例为1.2∶1。相应地,该前体煅烧后可以制备出棒状α-Al_(2)O_(3)和Al_(2)O_(3)-ZrO_(2)复合陶瓷粉体。

Influence of pre-synthesized Al_(2)O_(3)-SiC composite powder from clay on properties of low-carbon MgO-C refractories

To improve the properties of low-carbonization of MgO–C refractories,the introduction of composite additives is an effective strategy.Al_(2)O_(3)–SiC composite powder was prepared from clay using electromagnetic induction heating and carbon embedded methods.Further,the Al_(2)O_(3)–SiC composite powder synthesized by electromagnetic induction heating at 600 A was added into low-carbon MgO–C refractories(4 wt.%)to improve their properties.The results showed that when the addition amount of Al_(2)O_(3)–SiC composite powder is within the range of 2.5–5.0 wt.%,the properties of low-carbon MgO–C samples were significantly improved,e.g.,the apparent porosity of 7.58%–8.04%,the bulk density of 2.98–2.99 g cm-3,the cold compressive strength of 55.72–57.93 MPa,the residual strength after three air quenching at 1100°C of 74.86%–78.04%,and the decarburized layer depth after oxidized at 1400°C for 2 h of 14.03–14.87 mm.Consequently,the idea for the rapid synthesis of Al_(2)O_(3)–SiC composite powder provides an alternative low-carbon MgO–C refractories performance optimization strategy.

Synthesis and formation mechanism of nanocrystalline ZrB_(2)-Al_(2)O_(3)composite powders via an amorphous precursor

ZrB_(2)-Al_(2)O_(3)composite powders were synthesized at 1100℃using a novel ZrB_(2)precursor and Al powders as raw materials.The final ZrB_(2)-Al_(2)O_(3)composite powders consisted of submicron Al_(2)O_(3)and nanosize ZrB_(2)(50-100 nm)particles,which were homogeneously mixed in microscale.Combined with thermodynamic calculation and experiment results,the formation mechanism of ZrB_(2)-Al_(2)O_(3)composite powders was proposed as follows:ZrB_(2)precursor first decomposed into ZrO_(2)and amorphousB2O3.Aluminothermic reduction of ZrO_(2) and B_(2)O_(3) generated Zr and B atoms and the coproducts Al_(2)O_(3),and then,a series of reactions between Zr atoms,B atoms and Al took place to form ZrB_(2)and Al_(3)Zr.Then,ZrB_(2),Al_(2)O_(3)and Al were obtained through a liquid-solid reaction between Al_(3)Zr andB2O3,which is the limiting step in the conversion process.When the Al_(3)Zr was exhausted,the reaction between Al,ZrO_(2)and B became the main reaction to obtain ZrB_(2)and Al_(2)O_(3).

BN/Al_(2)O_(3)复合粉末及其聚合物基复合材料的制备与导热性能

采用固-液相共混法制备了多种BN/Al_(2)O_(3)复合粉末,通过冻融法和表面修饰法对BN进行了改性处理,改变表面修饰剂类型和摩尔比得到了前驱体和烧结态BN/Al_(2)O_(3)复合粉末,并利用机械混合法制备了聚合物基BN/Al_(2)O_(3)复合材料,并测试分析了其导热性能。结果表明,经冻融处理的BN分散性和界面相容性明显优于未经冻融处理的BN。多巴胺对BN的改性效果优于聚乙二醇。采用多巴胺作为表面修饰剂且BN与Al(NO3)3的摩尔比为1:1时,能够得到纳米Al_(2)O_(3)均匀包覆的微米BN粉末,即BN/Al_(2)O_(3)微纳复合粉末,其聚合物基复合材料的导热系数可达0.62 W·m^(-1)·K^(-1),是纯聚合物导热系数的3倍,是采用纯微米BN粉末制备的聚合物基复合材料导热系数的1.5倍。在BN表面附着的Al_(2)O_(3)可以形成层状热传导通道,能够有效提高聚合物基BN/Al_(2)O_(3)复合材料的热导率。

粉末烧结法和铸造法制备ZrO_(2)增韧Al_(2)O_(3)陶瓷颗粒增强高铬铸铁基复合材料及其耐磨性能

将粒径为1~2 mm的ZrO_(2)增韧Al_(2)O_(3)陶瓷颗粒(ZTA_(p))、高铬合金粉末和黏结剂混合真空烧结制备蜂窝状预制体,再浇注高铬铸铁液制备出ZTA_(p)增强高铬铸铁基复合材料。采用SEM、EDS、XRD分析复合材料的界面微观结构和物相组成,通过三体磨损试验评价复合材料的耐磨性能。结果表明,烧结高铬铸铁基体在铸造过程中发生重熔,与铸造高铬铸铁基体呈冶金结合,ZTA_(p)与金属基体界面结合致密,无裂纹、气孔等缺陷。复合材料三体耐磨性能达到高铬铸铁的3倍以上。将该复合材料应用于制备磨辊件,经过5000 h服役,柱状区和复合区在磨辊半径方向上的磨损量分别为8.2 mm、5.9 mm,预计寿命可达到高铬铸铁磨辊的2倍以上。

原位生成多尺度增强相提高Al_(2)O_(3)-SiC-C浇注料的性能

为了提高铁水预处理用耐火材料的物理性能和抗渣侵蚀性,在Al_(2)O_(3)-SiC-C耐火浇注料中引入不同含量的复合金属微粉(CMP),研究了其对Al_(2)O_(3)-SiC-C耐火浇注料显微结构、物理性能和抗渣侵蚀性能的影响。结果表明:CMP的加入能够促进试样中形成片状晶体、棒状纤维、细丝状纤维和晶须等多尺度增强相;随着CMP的加入,试样的常温抗折强度和耐压强度提高,当CMP加入量为6%(质量分数)时,浇注料的高温抗折强度提高了231%,热震水冷5次后试样的抗折强度保持率达到23%,比空白样提高了77%,抗渣侵蚀面积减小了37.2%。

化学共沉淀法制备纳米氧化铝粉

以分析纯的硝酸铝和碳酸氢铵为主要原料,采用共沉淀法制备纳米氧化铝粉体,研究反应物的加料顺序和加料速度、表面活性剂种类、溶剂组成、晶种及前驱体的煅烧温度对产物的影响。采用X射线衍射仪分析粉体的物相组成,用谢乐公式计算晶粒尺寸,采用透射电子显微镜观测颗粒形貌。结果表明:原料的加料顺序对产物影响不明显,用PEG6000作表面活性剂,水和乙醇等体积混合液作溶剂,Al(NO_(3))_(3)溶液直接倒入NH_(4)HCO_(3)溶液中制得前驱体,当煅烧温度为1135℃煅烧2 h时,制备了粒径为33 nm的α-Al_(2)O_(3)粉体,加入晶种后,煅烧温度可降低至1075℃。