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放电等离子烧结工艺对不导电材料整体电阻的影响 被引量:1

Influences of Spark Plasma Sintering Process on Overall Resistance of Non-conductive Materials
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摘要 基于Si3N4纳米陶瓷放电等离子烧结(SPS)试验数据,研究了不导电材料烧结过程中烧结系统整体电阻的变化规律。结果表明:烧结温度与烧结粉体高度是影响烧结系统整体电阻的两大因素,在烧结的升温阶段,电阻随着温度的升高和粉体高度的减小逐渐减小,当粉体烧结致密后,如果烧结温度继续升高,则电阻逐渐增大。根据烧结试验结果,得到了总电阻随烧结温度与粉体初始高度的变化曲线,并用SiC陶瓷材料的SPS试验数据对所拟合公式进行了验证,证明了该公式对不导电材料在SPS烧结过程中烧结系统整体电阻变化规律的适用性。 The overall resistance variation of sintering system on non-conductive materials in spark plasma sintering was studied based on experimental data of Si3 N4 nano-ceramic. Results show that sin- tering temperature and the height of the initial powder are the two key factors that affect the overall resistance. In the heating stage, the overall resistance gradually decreases with the rising of tempera- ture and reducing of initial powder height, but when the powder sintering,if the sintering temperature continues to raise, the overall resistance increases gradually. According to the sintering test results, the curve of overall resistance with the initial powder height and the sintering temperature was obtained. And with the SPS test data of SiC ceramic material on the fitting formula was verified, the applicabili- ty of the formula for the spark plasma sintering of non-conductive material was demonstrated.
作者 骆俊廷 刘永康 申江龙 张春祥
机构地区 先进锻压成形技术与科学教育部重点实验室(燕山大学) 燕山大学亚稳材料制备技术与科学国家重点实验室
出处 《中国机械工程》 EI CAS CSCD 北大核心 2015年第18期2524-2527,共4页 China Mechanical Engineering
基金 燕山大学青年教师自主研究计划资助项目(14LA002)
关键词 SI3N4 纳米陶瓷 不导电材料 放电等离子烧结 整体电阻 Si3 N4 nano-ceramic non-conductive material spark plasma sintering (SPS) overall re- sistance
分类号 TF124 [冶金工程—粉末冶金]
  • 相关文献

参考文献10

  • 1Gao Lian, Jin Xihai, Kawaoka H, et al. Microstruc- ture and Mechanical Properties of SiC- mullite Nanocomposite Prepared by Spark Plasma Sintering [J]. Material Science and Engineering A, 2002,334 (1/2) :262-265.
  • 2Roherto O, Licheri R, Locci A M, et al. Consoli- dation/Synthesis of Materials by Electric Current Activated/Assisted Sintering[J]. Materials Science and Engineering R ,2009,63(4/6) : 127-287.
  • 3骆俊廷,SUN Yan,ZHANG Chunxiang,ZHAO Zhiyong.Thermal-electrical Coupled Analysis and Experimental Investigation on Spark Plasma Sintering of SiC Ceramics[J].Journal of Wuhan University of Technology(Materials Science),2012,27(6):1120-1124. 被引量:2
  • 4Wolff C, Mercier S, Couque H, et al. Modeling of Conventional Hot Compaction and Spark Plasma Sintering Based on Modified Micromechanieal Mod- els of Porous Materials[J]. Mechanics of Materials, 2012,49:72-91.
  • 5Munir Z A. The Effect of External Electric Fields on the Nature and Properties of Materials Synthesized by Self-propagating Combustion[J]. Materials Sci- ence and Engineering,2000,287(2) :125-137.
  • 6Song Shixue, Wang Zhi, Shi Guopu. Heating Mechanism of Spark Plasma Sintering[J]. Ceramics International,2013,39 (2) :1393-1396.
  • 7Pavia A, Durand L, Ajustron F, et al. Electro-ther- mal Measurements and Finite Element Method Simulations of a Spark Plasma Sintering Device[J]. Journal of Materials Processing Technology, 2013, 213(8) :1327-1336.
  • 8Luo Junting,Liu Riping. Formation and Vanishment of the Intragranular Microstrueturein Si2N20/ Si3 N4 Nanocomposites[J]. Science in China Series E: Technological Sciences, 2010,53 ( ) : 286-289.
  • 9骆俊廷.Effect of Additives on the Sintering of Amorphous Nano-sized Silicon Nitride Powders[J].Journal of Wuhan University of Technology(Materials Science),2009,24(4):537-539. 被引量:3
  • 10孙燕,骆俊廷,江磊,张春祥.CuNi合金放电等离子烧结温度场的热电耦合分析[J].粉末冶金材料科学与工程,2012,17(1):25-31. 被引量:3

二级参考文献19

  • 1杨俊逸,李元元,李小强,郭亮,杨超.电场活化烧结温度场的数值模拟[J].机械工程材料,2006,30(11):73-76. 被引量:12
  • 2GAO L,JIN X H,KAWAOKA H,et al.Microstructure and mechanical properties of SiC mullite nanocomposite prepared by spark plasma sintering[J].Material Science and Engineering A,2002,334(1/2):262-265.
  • 3WU Y C,FENG Z Y.Study of temperature field in spark plasma sintering[J].Material Science and Engineering A,2002,90(1/2):34-37.
  • 4ZAVALIONGOS A,ZHANG J,KRAMMER M,et al.Temperature evolution during field activated sintering[J].Material Science and Engineering A,2004,379(1/2):218-228.
  • 5ANSELMI-TAMBURINI U,GENNARI S,GANAYA J E,et al.Fundamental investigations on the spark plasma sintering/synthesis process II.Modeling of current and temperature distributions[J].Materials Science and Engineering A,2005,394(1/2):139-148.
  • 6CHEN W,ANSELMI-TAMBURINI U,GANAYA J E,et al.Fundamental investigations on the spark plasma sintering/synthesis process I.Effect of dc pulsing on reactivity[J].Materials Science and Engineering A,2005,394(1/2):132-138.
  • 7ANSELMI-TAMBURINI U,GANAYA J E,MUNIR Z A.Fundamental investigations on the spark plasma sintering/synthesis process III.Current effect on reactivity[J].Materials Science and Engineering A,2005,407(1/2):4-30.
  • 8DEVESH T,BIKRAMJIT B,KOUSHIK B.Simulation of thermal and electric field evolution during spark plasma sintering[J].Ceramics International,2009,35(2):699-708.
  • 9Luo Junting Ph D,Zhang Kaifeng,Wang Guofeng,Han Wenbo.Fabrication of fine-grained Si3N4-Si2N2O composites by sintering amorphous nano-sized silicon nitride powders[J].Journal of Wuhan University of Technology - Mater Sci Ed.2006(3)
  • 10Junting Luo,Kaifeng Zhang.Superplasticity and Sinter-forging of Fine-grained Si3N4-Si2N2O Composite[].Materials Sci- ence Forum.2004

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中国机械工程
2015年 第18期

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