熔渗

Ti（C，N）基金属陶瓷熔渗/氮化复合表面处理

Multiple Surface Treatment of Ti ( C , N ) - based Cermet by Melt Infiltration and Nitridation

真空&压力熔渗制备B4C基金属陶瓷复合材料的研究

Study on boron carbide-aluminum composite by vacuum-pressure infiltration

熔渗烧结制备Ti3SiC2反应机理的研究熔析法-金属精炼

Study on the reaction mechanism of Ti_3SiC_2 by melt infiltration sintering method

烧结熔渗过程中W和Ti扩散溶解的研究

Diffusion of W and Ti during Sintering and Infiltration

高体积比SiCp/6013Al复合材料反应熔渗制备与热学性能

Reactive Infiltration Processing and Thermal Properties of SiC_p / 6013Al Composite with High SiC Particle Content

树脂膜熔渗工艺用FRP模具的设计与制备

Design and Manufacture of FRP Mould in RFI Experiment

合金元素Ni、Mo、W及熔渗铜对烧结钢耐磨性的影响

Influence of alloy elements Ni 、 Mo 、 W and copper infiltrated on wear resistance of sintered steels

采用先烧结骨架再渗Cu的熔渗工艺制备了一系列WCr／Cu复合材料。

W - Cr / Cu composites were prepared by infiltration method .

确定了Al-Si复合材料压力熔渗和热挤压工艺参数；

The processing parameters of pressure infiltration and hot extrusion were confirmed .

临界熔渗压力与SiC颗粒尺寸及反应程度有关。

The critical pressure for preparation is related to the dimension of SiC particles and extent of the reaction .

本文用包埋熔渗法和气相沉积法分别制备了SiC涂层。

In this paper , using embedding melt infiltration method and deposition method , we prepared the SiC coating .

H2气氛熔渗CuW触头材料性能的研究

Study on Properties of CuW Contact Infiltrated under H2 Atmosphere

用反应压力熔渗法制备高含量SiCP/6013Al复合材料及其力学性能

Preparation of SiCp / 6013Al Composite with High SiC Particles Content in Reactive Pressure Infiltration Processing and Its Mechanical Properties

针对轴向、径向两种压制方向成型的WCu合金，采用烧结熔渗法制备WCu/Cu整体电触头材料，测定结合面的抗拉强度及WCu合金的电性能、显微组织和抗弯强度。

W-Cu and copper solid electrical contact materials , which were prepared by axial and radius direction pressing were fabricated by sintering-infiltration method .

PDC材料烧结过程中钴在金刚石层中的扩散熔渗迁移机制

Diffusion and Infiltration Mechanisms of Cobalt through Diamond Layer during the Sintering of Polycrystalline Diamond Compacts

添加15%Mo对反应熔渗Al制备MoSi2复合材料组织和力学性能的影响

The Effect of 15 wt % Mo Addition on the Microstructure and Mechanical Properties of MoSi_2 Composite

熔渗反应法制备MoSi（2-）SiC复合材料性能的影响因素

Influence Factor of MoSi_ ( 2 - ) SiC Composites Synthesised by Reactive Infiltration Processing

分析了压力熔渗和热挤压工艺对Al-Si复合材料成形性、组织和性能的影响；

The influences of the processing parameters on the formability , the microstructure and the properties of Al-Si composites were discussed .

结果表明：利用熔渗法可制备高致密的316L不锈钢，相对密度可达98%以上；

The results show that it is possible to produce 316L stainless steel by using the infiltration technology .

熔渗法CuW触头材料W骨架压坯密度理论计算公式的研究

Study on the Calculated Formula of the Green Density of W Skeleton of CuW Contact Materials Manufactured by Infiltration

反应熔渗烧结法制备MoSi2/SiC复合材料

Mosi_2 / sic composite prepared by using reaction - melting infiltration sintering

文摘通过模具材料的选择、分型和模具中加热装置的合理设计，制备出树脂膜熔渗工艺（RFI）实验用FRP模具。

Though selection of mould materials and reasonable design of parting line and mould heating system , FRP mould is manufactured .

采用反应熔渗法在低压力下制备高体积比SiCp/Al复合材料，并研究其热学性能。

The SiC p / Al composite with high SiC particle content is prepared by reactive infiltration under low pressure , and the thermal properties of the composite are investigated .

熔渗和液相法烧结Mo-Cu合金的组织和性能

Tissues and Properties of Mo-Cu Alloy Prepared by Infiltration and Liquid-phase Sintering

树脂膜熔渗工艺（RFI）是一种新型的复合材料成型工艺。

Resin film infusion ( RFI ) is a new technique for the manufacture of composite structures .

钨粉粒径对熔渗法制备的CuW触头材料硬度的影响

Effects of Tungsten Powder Size on Hardness of W-Cu Contact Produced by Infiltration

用熔渗法制备的W-cu复合材料在小批量生产时，发现熔渗结束后样品的热导率数据分散不稳定，受熔渗时摆放位置的影响很大。

The thermal conductivity of W-Cu composites is affected by the position where they were placed in during infiltrating .

熔渗法AgW（75）触头材料研究

Study of AgW ( 75 ) Electrical Contact Material With Infiltration Technology

对粉末冶金熔渗技术制备的不同成分WCu合金在-196℃，保温48h进行深冷处理。

W-Cu alloys prepared by powder metallurgy infiltration method were treated at - 196 ℃ for 48h .

采用粉末注射成形制备SiC预成形坯和铝合金无压熔渗相结合的技术，成功制备出高体积分数且形状复杂的SiCp/Al复合材料零件。

The high reinforcement volume fraction SiC_p / Al composite parts with complex shape can be produced successfully by combination of powder injection molding ( PIM ) for SiC preform preparation and aluminum pressureless infiltration .