微波烧结

Al2O3陶瓷的微波烧结均匀场条件研究

Homogeneous Field Conditions of Al_2O_3 Ceramics Microwave Sintering

添加Y2O3的自蔓延高温合成β-Sialon粉的微波烧结

Microwave Sintering of SHS-Prepared β - Sialon Powders with Y_2O_3 as Additive

并分析了微波烧结和等离子活化烧结制备Ti（C，N）基金属陶瓷的可能性。

The possibility of plasma activated sintering and microwave sintering is analyzed .

掺杂TiO2的Li1+xV3O8微波烧结样进一步改善了电化学性能。

TiO2 doped further improved the electrochemical performance .

微波烧结ZrO（2（n））增韧Al2O3复合陶瓷组织与性能研究

Study on Microwave Sintering Structure and Properties of ZrO_ ( 2 ( n )) - Al_2O_3 Composite Ceramics

微波烧结样品的通流量Im更是比传统烧结样品高约50%。

Especially , the surge current Im is about 50 % higher than that conventional sintered .

系统探讨了微波烧结Cu粉及TiB2/Cu复合粉末压坯的各种影响因素。

Various kinds effect factors of the Cu powder and TiB2 / Cu composite powder compact sintered by microwave were systematically studied .

微波烧结法制备Ba（0.65）Sr（0.35）TiO3热释电陶瓷

Ba_ ( 0.65 ) sr_ ( 0.35 ) tio_3 pyroelectric ceramics prepared by microwave sintering

微波烧结和常压烧结对Al2O3-ZrO2陶瓷磨损行为的影响

Influences of Microwave and Conventional Sintering on the Wear Behavior of Al_2O_3-ZrO_2 Ceramics

纳米Al2O3-ZrO2（3Y）复相陶瓷的微波烧结

Microwave sintering of Nano-Al 2O 3-ZrO 2 ( 3y ) multiphase ceramics

氧化物电子陶瓷微波烧结用保温材料MgAl2O4-LaCrO3的研究

MgAl_2O_4-LaCrO_3 Insulator Materials for the Microwave Sintering of Electronic Oxide Ceramics

微波烧结ZrO2/LaNbO4-MoSi2复合陶瓷耐磨性研究

Research on Wear Character of Microwave Sintering ZrO_2 / LaNbO_4-MoSi_2 Ceramic Composites

锂嵌脱化合物LiMn2O4的微波烧结研究

The study on Li based intercalation compound LiMn 2O 4 synthesized by microwave sintering

微波烧结Al2O3-TiC复合材料的研究

Study on microwave sintering of al_2o_3-tic Composites

3微波烧结Al2O3-ZrO2纳米陶瓷材料具有烧结温度低、烧结时间短、烧结前后晶粒度尺寸变化很小，烧结致密均匀的优点。

Microwave sintering of alumina-zirconia nano-ceramic has lower sintering temperature , shorter preservation time , little grain size growth .

PLZT的粉末合成及其微波烧结工艺研究

Synthesis of PLZT Powder and Research on Microwave Sintering Technique of PLZT

微波烧结PTCBaTiO3陶瓷的工艺与性能研究

Research on the Sintering Technology and Property of PTC BaTiO_3 in Microwave

常压烧结与微波烧结ZTA陶瓷性能

Properties of ZTA Ceramics Made with Microwave and Conventional Sintering Method

微波烧结ZTA陶瓷力学性能研究

Study on the Mechanical Properties of Microwave Sintered ZTA Ceramics

本文介绍了影响微波烧结的因素，以及Beta氧化铝、氧化锆、氧化铝等陶瓷制品的微波烧结和对微波效应的探讨。

In this paper , the influencing factors on the microwave sintering and its application to the sintering of beta-alumina , zirconia and alumina was introduced .

介绍了微波烧结技术的原理和特点，通过采用微波烧结技术制备了钙钛矿型复合氧化物载体及相应的Pd负载钙钛矿型催化剂。

The principle and characteristics of the microwave sintering technology are summarized . The perovskite-type metal oxides supports and the corresponding supported Pd catalyst are prepared by microwave sintering technology .

影响ZTA陶瓷微波烧结的主要工艺过程

Processes Affecting Microwave Sintering of ZTA Ceramics

本论文采用微波烧结技术并结合纳米Si3N4或BN粒子复合制备了Ti（C，N）基金属陶瓷。

In this paper , Ti ( C , N ) - based cermets reinforced by Nano - ( Si3N4 / BN ) particle were prepared by a microwave sintering .

W-Ni-Fe高密度合金的微波烧结

Microwave sintering of W-Ni-Fe heavy alloys

介绍了利用微波烧结技术小批量生产高磁导率Mn-Zn铁氧体的烧结工艺与设备。

This paper introduced the microwave sintering equipments and sintering process for small mass-production of high-permeability Mn-Zn ferrite .

单钩真空抛丸清理机单模微波烧结腔内电磁场分布规律及其影响因素的HFSS仿真研究

Hook type airless shot blasting machine Simulation of Influences on Distribution of Electromagnetic Field in Single Mode Sintering Cavity by HFSS

结果表明：微波烧结Al2O3TiCMoNi纳米金属陶瓷在1500℃的温度下保温10min时，可达到99.0%的相对密度；

The results show that the microwave sintered high purified Al_2O_3-TiC-Mo-Ni nanometer cermet can reach 99 % relative density at 1 500 ℃ sintering temperature for 10 minutes preservation ;

粉末冶金Fe-Cu-C合金的微波烧结研究

A Study of Microwave Sintered Fe-Cu-C PM Alloy

依此，通过对研制核心设备所存在技术难题的分析和解决，成功构建了一套SR-CT技术专用的微波烧结在线实验系统。

According to this , a set of SR-CT technology based microwave sintering analyze system was successfully built .

本文选用微波烧结新工艺，对ZTA陶瓷力学性能进行了研究，获得了较传统烧结工艺优良的陶瓷抗奇强度和断裂韧性。

Microwave Sintering , as a new technology used on the study of ZTA ceramic mechanical properties , makes the bending strength and the fracture toughness developed .