Microstructural characterization of titanium matrix composite coatings reinforced by in situ synthesized TiB + TiC fabricated on Ti6Al4V by laser cladding

Titanium-based composite coatings reinforced by in situ synthesized TiB and TiC particles between titanium and B4C were successfully fabricated on Ti6Al4V by laser cladding. Phase constituents of the coatings were predicted by thermodynamic calculations in the Ti-BnC-Al and Ti-B-C-Al systems, respectively, and were validated well by X-ray diffraction （XRD） analysis results. Microstructural and metallographic analyses were made by scanning electron microscopy （SEM） and electron probe micro-analysis （EPMA）. The results show that the coatings are mainly composed of α-Ti cellular dendrites and the eutecticum in which a large number of needle-shaped TiB and a few equiaxial TiC particles are embedded. C is enriched in α-Ti cellular dendrites and far exceeds the theoretical maximum dissolubility, owing to the extension of saturation during laser cladding. The coatings have a good metallurgical bond with the substrate due to the existence of the dilution zone, in which a great amount of lamella β-Ti grains consisting of a thin needle-shaped martensitic microstructure are present and grow parallel to the heat flux direction; a few TiB and TiC reinforcements are observed at the boundaries of initial β-Ti grains.

NiAl复合涂层中强化相的形成机理及其对磨损性能的影响

目的提高NiAl复合涂层的硬度,扩大它作为涂层材料在矿山机械和石油化工领域的应用范围。方法TiC、TiB_(2)金属陶瓷颗粒具有较高的熔点、硬度、弹性模量及较好的化学稳定性,是一种优良的高温结构材料。采用等离子熔覆技术在Q235低碳钢表面制备NiAl金属间化合物涂层和TiC-TiB_(2)强化NiAl复合涂层,研究涂层的微观组织结构、金属粉末反应热力学、TiC-TiB_(2)强化相的形成机理和涂层的摩擦行为。结果涂层组织紧密、均匀,涂层与基体具有良好的冶金结合。NiAl涂层主要由NiAl、γ-(Fe,Ni)固溶体组成。复合涂层由NiAl、Ni_(3)Al、γ-(Fe,Ni)、TiC和TiB_(2)增强相组成。TiC相呈小块状,TiB_(2)相呈短棒状。粉末反应的热力学计算进一步证明了强化相TiC、TiB_(2)的形成。强化相的形成机理与原子扩散沉淀和晶体结构有关。与NiAl涂层相比,复合涂层的平均硬度从416HV提高到525HV,摩擦因数和磨损失重(质量损失)从0.68、0.376 g分别降至0.54、0.192 g。NiAl涂层磨损表面出现较多大且深的犁坑,NiAl复合涂层磨损表面较为平滑,只有少量浅犁沟。结论TiC和TiB_(2)主要通过溶解、扩散和沉淀析出方式形成。NiAl复合涂层具有高硬度、低摩擦因数和较少的磨损失重,具有优异的耐磨性能。在基体中弥散分布的小块状TiC颗粒和组织稳定性高的强化相有利于提高NiAl复合涂层的硬度和磨损性能。NiAl涂层的磨损机理主要为黏着磨损,复合涂层的磨损类型以磨粒磨损为主。

防结渣复合陶瓷涂层在燃用准东煤锅炉上的应用研究

针对某台670t/h燃用准东煤锅炉出现的沾污、结渣问题,在水冷壁和屏式过热器区域受热面喷涂复合陶瓷涂层.采用热力计算方法,并结合复合陶瓷涂层试验数据,对水冷壁和过热器的吸热量进行计算,确定了水冷壁与过热器的最佳喷涂面积.结果表明:喷涂复合陶瓷涂层后,锅炉运行一年后的沾污、结渣情况得到明显改善,吹灰器月投运时间和减温水量分别减少了58.2%和75.2%,但由于水冷壁与过热器的吸热量比例失调,出现了过热汽温偏低问题;在水冷壁与过热器的最佳喷涂面积下过热汽温达到设计值,减温水量适中.

复相陶瓷涂层Al-TiO_2-B_2O_3体系热力学与动力学分析

采用Al-TiO2-B2O3反应体系并利用机械合金化(MA)原位合成Al2O3-TiB2复合相,对Al-TiO2-B2O3反应体系标准反应吉布斯自由能(ΔGT)进行计算,并应用Starink法计算其反应活化能,计算结果表明:Al2O3和TiB2的生成可能性较大,XRD分析的结果也证实了这一点;利用差示扫描量热分析(DSC)对反应体系进行了研究,分析了Al2O3-TiB2复合相的生成过程;MA5h后粉体的Ea为361.35kJ·mol-1,MA20h后粉体的Ea为188.35kJ.mol-1。

燃煤锅炉防结渣复合陶瓷涂层技术应用

针对某台260 t/h燃煤锅炉沾污结渣问题,在受热面喷涂防结渣复合陶瓷涂层,根据结渣部位,结合热力计算方法,得出最佳喷涂区域为从下二次风底部往上12 m的四周水冷壁,面积约为400 m2。喷漆后运行3个月的统计结果显示:锅炉的沾污结渣情况明显改善,炉膛温度显著降低,月吹灰频次下降95.5%,减温水量下降34.5%;但存在飞灰及炉渣含碳量增加问题。对此,可采用降低煤粉细度等方式改善。本文研究结果可为解决锅炉结渣问题提供较好途径。

激光熔覆生物陶瓷涂层及界面的热力学计算

在医用金属材料表面形成一层生物陶瓷是制备高性能、高可靠性生物植入材料的有效途径.采用激光处理技术在钛合金表面同步合成及熔覆了以羟基磷灰石为主的生物陶瓷涂层复合材料.激光熔覆制备生物陶瓷涂层及界面反应是非常复杂的过程,其中包括很多的化学反应.从物理化学角度对涂层及界面反应进行热力学计算.计算结果表明:在该实验条件下,完全具备合成羟基磷灰石、磷酸钙等生物陶瓷涂层的热力学条件,而且也满足界面处发生化学反应生成钛酸钙等新相的条件.