1) ceramic phase
陶瓷相
1.
Relationship between the wettability of ceramic phases in cermets and their valence electron structures;
金属陶瓷中陶瓷相的润湿性与其价电子结构的关系
2.
Research on Organize and Property of Ceramic Phase Strengthening Ferro-base Weld Metal Overlay
陶瓷相增强铁基耐磨堆焊层组织与性能的研究
3.
The emphases are put on how to select the ceramic phase and binding metal of the ceramic-metal coating and how to select laser cladding process.
从激光熔覆金属陶瓷技术的工艺方法以及金属陶瓷复合层中硬质陶瓷相、粘结金属类型的选择3个方面综述了激光熔覆金属陶瓷技术的发展概况。
2) ceramic phases
陶瓷相
1.
It can be seen that ceram melts partly and scatters and precipitates tiny ceramic phases under the action of high temperature by arc plasma,precipitated TiC presens namometer magnitude,and antiphase domain exsits in cladding,which is called plasma irradiation in.
用等离子弧扫描涂覆涂料的金属表面 ,形成了含有陶瓷相的熔覆层 ,借助金相显微镜、电子探针、透射电镜等分析测试了涂层中组织和陶瓷相的行为。
2.
An investigation has been made on how the ceramic phases are distributed in the laser-clad ceramic metal composite coatings(LCCCs)with different weight percentages and sizesof WC particles as well as with different laser-cladding methods and processing parameters.
系统研究了不同含量和粒度WC颗粒以及不同熔覆方式与工艺参数下,激光熔覆层中陶瓷相的分布状态,采用图像分析仪测定了陶瓷相的分布密度与间距。
3) ceramics
[英][si'ræmiks] [美][sə'ræmɪks]
陶瓷相
1.
X -ray diffraction(XRD), scanning electron microscope(SEM), transmission electron microscope(TEM) and high resolution electron microscope(HREM) were employed to investigate the core/rim structure of ceramics in Ti(C,N) based cermets.
用XRD ,SEM ,TEM和HREM观察、分析的方法研究了Ti(C ,N)基金属陶瓷中陶瓷相的芯、壳组织 。
2.
The relation between the valence electron structure of ceramics and the bending strength of cermets is discussed.
利用固体与分子经验电子理论,计算了金属陶瓷中三元复合陶瓷相(Ti,Mo,W)C、四元复合陶瓷相(Ti,Mo,W,Nb)C和(Ti,Mo,W,Ta)C、五元复合陶瓷相(Ti,Mo,W,Nb,Ta)C的价电子结构,探讨了陶瓷相的价电子结构与金属陶瓷抗弯强度的关系,提出了判据关系式,此外,还进行了抗弯强度的实验验
4) composite ceramics
复相陶瓷
1.
Preparation of cordierite-mullite composite ceramics;
堇青石-莫来石复相陶瓷制备
2.
Sintering behavior and dielectric property of BST-BZN composite ceramics
BST-BZN复相陶瓷的烧结行为和介电性能
3.
Study on the dielectric properties of MgO-Ba(Zr_(0.2)Ti_(0.8))O_3 composite ceramics
MgO-Ba(Zr_(0.2)Ti_(0.8))O_3复相陶瓷介电性能研究
5) composite ceramic
复相陶瓷
1.
Effect of BN content on the properties and microstructure of AlN-BN composite ceramics by injection molding;
BN含量对注射成形AlN-BN复相陶瓷性能和组织的影响
2.
Preparation of Al_2O_3-based composite ceramics by combining hydrothermal processing with co-precipitation;
Al_2O_3基复相陶瓷共沉淀—水热法制备研究
3.
3SrO·(1-y)TiO2·yNb2O5)composite ceramics were prepared by sol-gel method in which BST slabby sol solution were fabricated firstly to suspend Nb2O5 fine powders.
yNb2O5)复相陶瓷。
6) multiphase ceramic
复相陶瓷
1.
Preparation and characteristics research of the doping W~(6+) into Zr(WV)_xO_y multiphase ceramic
掺杂W~(6+)的Zr(WV)_xO_y质复相陶瓷的制备及特性研究
2.
Nano multiphase ceramic helix muzzle was made of nano-ZrO2 and micron Al2O3, experiment results proved that nano-ZrO2 help to preparation thin crystal ZTA multiphase ceramic.
以纳米ZrO2、微米Al2O3为原料制备纳米复相陶瓷喷嘴。
3.
Friction and wear behaviors were studied for Ti_3SiC_2/SiC multiphase ceramics/45 steel pairs under unlubricated and lubricated.
研究了由热等静压原位合成的Ti3SiC2/SiC复相陶瓷与45#钢在干摩擦和边界油润滑条件下的摩擦磨损特性。
补充资料:陶瓷表面、界面和界相
陶瓷表面、界面和界相
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陶瓷表面、界面和界相。eramiC Surfaee inter-face and interphase任何固体材料都有表面。表面的结构和原子排列决定能量状态,因而影响材料的性能,尤其是电性能和光学性能,并决定材料是否具有催化性能。利用一些陶瓷表面结构与湿度的密切关系,可制成湿度探测器。如用多孔氧化铝膜制造成的湿度探测器,被探测的水气通过可渗透的顶部金质电极在多孔A12O3壁上达到平衡,这一情形改变结构通道,因而具有表面电导性能。 表面科学必然涉及界面问题。晶界是多晶材料(陶瓷是一种典型的多晶材料)中最常见的界面现象。作为多晶材料中分割晶粒的界面,可看成材料从一个晶粒向另一个晶粒的结构过渡形式。晶界的宽度一般为原子间距的数量级,可认为是二维和三维的中间状态。晶界的化学成分,尤其是杂质的成分,影响陶瓷材料的强度,特别是高温强度、蠕变性能、硬度等。晶界组成可影响陶瓷材料的烧结机理属性、晶粒的重结晶,并改变晶界的相变。在功能陶瓷中,如电容器陶瓷、正温度系数(PTC)陶瓷等,晶界在调节材料的性能上是重要的因素。对于很多材料,要求晶界尽量“清洁”,即没有杂质和第二相。对于半导体材料,由于晶界的存在产生悬键,从而给出具有扰动特性的空域能带。若有杂质富集,将改变能带状态,因此这类材料需要清洁晶界。材料界面中薄膜和底材之间形成的界面所产生的缺陷,对半导体材料电性能影响很大,因此制备时要加以控制。 随着界面问题的深入研究,以及多相体系在材料中的日趋重要,又提出了界相这一概念。所谓界相是指不同相之间的界面。在多相复合陶瓷中,有纤维或晶须与母相之间、有两相弥散与母相之间、有两个或多个主晶相之间,以至在陶瓷相与金属相、陶瓷相与高分子相之间的界相问题。它们在化学上的相容、在物理上的匹配,以及结合性状和显微结构,均为这类陶瓷材料的设计提供了有用的信息和依据。‘ (温树林)
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