Ti_(33)V_(20)Cr_(47)合金粉末吸氢动力学研究(英文) 被引量：1

Kinetics of Hydrogen Absorption for Ti_(33)V_(20)Cr_(47) Alloy Powder

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摘要研究了温度、初始压力、粒度对Ti33V20Cr47合金吸氢动力学性能的影响。研究发现,合金的吸氢过程控速环节为三维扩散,表观活化能为25.7±0.8kJ/mol。合金的反应速度随温度的升高而加快。由于Ti33V20Cr47合金有2个吸氢平台,在1.5MPa和2.5MPa压力下比在3.5MPa压力下更先完成吸氢。合金反应速度随合金粒度的增大而加快。原因是合金吸氢过程为放热过程,粒度越大,吸氢产生的热量越不容易耗散,温度越高,导致吸氢越快。 Influences of temperature,initial pressure and particle size on the hydriding reaction kinetics of Ti33V20Cr47 alloy powder was analyzed and discussed.It is found that the rate-controlling step of the hydriding processes is hydrogen diffusion with the activation energy of 25.7±0.8 kJ/mol.The reaction rate can be accelerated with the increase of temperature.The Ti33V20Cr47 alloy can finish hydrogen absorption faster under the initial pressure 1.5 MPa and 2.5 MPa than under the initial pressure 3.5 MPa because it has two plateaus.The reaction rate can also be accelerated with the increase of particle size.The possible reason could be related to the fact that the large particle size is adverse for the dissipation of reaction heat,thus leading to the rise of the alloy temperature.

作者孔祥成杜俊霖王坤李志林吴铸

机构地区中国科学院上海微系统与信息技术研究所中国科学院研究生院

出处《稀有金属材料与工程》 SCIE EI CAS CSCD 北大核心 2012年第11期1899-1902,共4页 Rare Metal Materials and Engineering

基金 National“863 Program”(2007AA05Z149) Science and Technology Commission of Shanghai Municipality(09dz1206800)

关键词吸氢动力学扩散 hydrogen absorption kinetic mechanism diffusion

分类号 TF122 [冶金工程—粉末冶金]

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Ti_(33)V_(20)Cr_(47)合金粉末吸氢动力学研究(英文) 被引量：1

参考文献12

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