摘要
With nano-SiC as matrix,nano-TiN as reinforcement phase,de-ioned water as dispersion medium,TMAH as dispersant and Y3Al5O12(YAG) as additive,nano-SiC based aqueous slurries were prepared,and the effects of solid phase content and dispersant content on rheological properties,dispersibility and stability of the slurries were analyzed.The results showed that shear viscosity and shear stress of aqueous SiC based slurries increased with the increase of solid phase content,and decreased with the increase of TMAH content.The dispersibility and stability of the slurries both increased with the increase of solid phase content and TMAH content.The aqueous SiC based slurry was pseudo-plastic non-Newtonian fluid with shear-thinning property.The nanoparticles in the slurry were 'parceled' or 'fixed' by YAG sol with network structure to form approximate aggregate with the size of 50—100 nm,which resulted in the stability and dispersion of nanoparticles.
With nano-SiC as matrix,nano-TiN as reinforcement phase,de-ioned water as dispersion medium,TMAH as dispersant and Y3Al5O12(YAG) as additive,nano-SiC based aqueous slurries were prepared,and the effects of solid phase content and dispersant content on rheological properties,dispersibility and stability of the slurries were analyzed.The results showed that shear viscosity and shear stress of aqueous SiC based slurries increased with the increase of solid phase content,and decreased with the increase of TMAH content.The dispersibility and stability of the slurries both increased with the increase of solid phase content and TMAH content.The aqueous SiC based slurry was pseudo-plastic non-Newtonian fluid with shear-thinning property.The nanoparticles in the slurry were "parceled" or "fixed" by YAG sol with network structure to form approximate aggregate with the size of 50—100 nm,which resulted in the stability and dispersion of nanoparticles.
出处
《化工学报》
EI
CAS
CSCD
北大核心
2010年第12期3309-3314,共6页
CIESC Journal
基金
高等学校博士点基金新教师资助项目(20070335017)
教育部重点科技项目~~
关键词
水基料浆
纳米碳化硅
流变性能
分散稳定性
aqueous slurry nano-SiC rheological property dispersibility and stability
