1) Self-suspension Method
自悬浮法
2) flow-levitation method
自悬浮定向流法
1.
Microstructure and properties of nano-copper powders prepared by flow-levitation method;
自悬浮定向流法制备纳米Cu粉的微结构和性能表征
2.
Ag nanoparticles were prepared by flow-levitation method.
采用自悬浮定向流法制备纳米Ag粉。
3.
Al nanoparticles were prepared by flow-levitation method.
采用自悬浮定向流法制备金属纳米A l粉。
3) Flow-levitation-cold-pressing method
自悬浮-冷压法
4) flow-levitation-molding method
自悬浮-模压法
1.
In order to study the properties and microstructure of the nanocrystalline metals prepared by flow-levitation-molding method,the nano-Cu particles synthesized by flow-levitation method were compacted in high-strength die at room temperature and the nanocrystalline Cu was obtained.
为了研究自悬浮-模压法制备的纳米金属晶体材料的有关性能及微观结构特征,采用自悬浮定向流技术制备出纳米Cu粉,经过常温模压得到金属Cu纳米晶体材料,测试了样品的室温显微硬度,并探讨了不同的压制工艺对金属Cu纳米晶体材料显微硬度的影响;利用X射线衍射谱和正电子湮没技术分别分析了纳米Cu晶体的平均晶粒尺寸和其内部的孔隙状态。
5) self-suspension
自悬浮
1.
Magnetomechanical modeling of magnet immersed in magnetic fluid and controllability of self-suspension
永磁体在磁流体中的磁力学建模及自悬浮位置可控性
6) aqueous suspension
水悬浮法
1.
In this article, the process of snitched continuous glass fiber mat reinforced PVC composites by aqueous suspension is studied.
介绍了水悬浮法制备连续玻璃纤维针刺毡增强PVC复合材料(PVC/GMT)的成型工艺。
2.
The compatibility of macromolecular binder in suspension solution and PVC resin in glass fiber/PVC composites prepared by aqueous suspension is studied by using DMA,DSC.
采用DMA、DSC、SEM等手段研究了水悬浮法制备的GF (玻璃纤维 ) /PVC (聚氯乙烯树脂 )复合材料中PVC与悬浮液高分子粘结剂的相容性 ,并探讨了其对复合材料性能的影响。
3.
In consideratioin of technical properties of GF/PVC composite materials prepared with aqueous suspension, a model interfacial design is carried out on fiber/matrix interfacial structures, and serial materials are prepared according to the design.
根据水悬浮法制备GF/PVC复合材料工艺的特点 ,对材料中的纤维 /基体的界面结构进行了模型界面设计 ,并根据设计方案制备系列材料 ,考察在材料制备中界面形成的机理及界面层结构与材料性能的关系。
补充资料:不可定向流形
不可定向流形
non - orientabte manifold
不可定向流形【曲一面兹血b睦n.l词rOId;ueopMe附Py-eMoe M.roo6Pa3.e」 不允许有定向(orie血泣由n)的流形(n坦nifo』d),例如加肠肠侣带(M6bi铭s苗P),刃d.曲面(Klein sul企ce)和偶数维的射影空间RP”. M.H.Bo血硬。xoB以戒撰薛春华译
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条