钛酸钾镁和钛酸铁钠片晶填充树脂基刹车片性能对比

本文对钛酸钾镁(TERRACESS)和钛酸铁钠(TFN)片晶粒度、水分、形貌和热率进行分析对比;采用Chase摩擦试验机和XD-MSM型定速摩擦试验机考察填充2种片晶对刹车片摩擦磨损性能的影响,并进行硬度和压缩性能测试。结果表明:TERRACESS和TFN片晶具有类似的晶体结构和颗粒形貌,且水质量分数和热率相当。填充2种片晶后的刹车片硬度和压缩性能相当。Chase实验表明2种刹车片摩擦性能都达到FF级水平;定速实验表明:TFN填充的刹车片比TERRACESS填充的刹车片具有更优异的高温耐磨性能,在300和350℃时磨损率分别下降了19%和53%。TFN具有更优异的性价比,可以替代TERRACESS在刹车片中推广应用。

片状钛酸钾镁对摩擦材料性能的影响

钛酸钾晶须已被广泛用作刹车片的增强材料,但纤维状的钛酸钾晶须在生产过程中极易飘散,被人体吸入后会造成严重的健康损害。因此,探寻更加环保的钛酸钾晶须的替代材料具有十分重要的意义。本工作以片状钛酸钾镁替代钛酸钾晶须,并进行了其含量对摩擦材料的力学性能和摩擦磨损性能影响的试验研究。试验结果表明:随着片状钛酸钾镁含量的增加,材料的冲击韧性下降,但都大于0.45 J/cm^(2),洛氏硬度保持在80HRM左右,满足了摩擦材料的力学性能要求;当钛酸钾镁含量为14%(质量分数,下同)时,摩擦表面能形成稳定的摩擦膜,100~350℃时其摩擦系数保持在0.35~0.48,材料的总磨损率为0.54×10^(-7)cm^(3)/(N·m),此时材料的摩擦磨损性能最佳。随着片状钛酸钾镁含量的增加,材料的热衰退率显著下降,明显优于钛酸钾晶须增强的摩擦材料,因此片状钛酸钾镁可以完全代替钛酸钾晶须成为更加环保的增强材料。

煅烧工艺对熔盐法合成钛钾镁片晶的影响

钛酸镁钾具有优异的力学性能,被广泛用作各类高级轿车刹车片的摩擦材料。而材料的组成及形貌对刹车效果的影响很大,传统的合成工艺无法对其进行有效地控制。本文通过对煅烧工艺的优化,从而得到结晶度和形貌俱佳的钛酸镁钾片晶。以Mg(OH)_2、K_2CO_3和TiO_2为原料,加入KCl为熔盐,采用熔盐法合成钛酸钾镁片晶(KMTO)。利用X射线衍射仪(XRD)和扫描电子显微镜(SEM)技术手段研究了煅烧工艺(升温速率、煅烧温度、保温时间)对钛酸钾镁片晶组成及形貌的影响,并对其反应机理进行了初步的探讨。结果表明,不同的煅烧工艺对熔盐法合成钛酸镁钾片晶的组成及形貌产生了显著的影响,以200℃/h升温至800℃后,再以100℃/h升温至1000℃,保温2 h,通过水洗干燥,即可得到结晶度较高、形貌比较均匀的K_(0.8)Mg_(0.4)Ti_(1.6)O_4片晶。

Synthesis of platy potassium magnesium titanate and its application in removal of copper ions from aqueous solution

Platy potassium magnesium titanate (K0.8Mg0.4Ti1.6O4, KMTO) was synthesized by a flux method. The potential application of KMTO in removing copper ions from water pollutants was investigated. The crystal phases of specimens were identified by XRD. The morphology and structural information were characterized by SEM and TEM. The adsorption behavior under different conditions was investigated, including different pH values and different initial copper ion concentrations. The results show that the maximum adsorption capacity of Cu(II) ions is 290.697 mg/g, and almost 99.9% of Cu(II) ions can be removed, which is much higher than that of other sorbents reported. The kinetics of KMTO for the adsorption of Cu(II)ions was studied and the best fit can be obtained by the pseudo-second-order model. Adsorption isothermal data can be well interpreted by the Freundlich equation (R2=0.991). In conclusion, this study highlights that KMTO is a potential material for the efficient removal of heavy metal ions in polluted water. It also opens up a new opportunity for the applications of platy KMTO.