Your search keyword '"Huisheng Lv"' showing total 4 results

1. Effect of the drying process on the preparation of porous silica microspheres

Author

Huisheng Lv, Yanpeng Sun, Zhongfeng Geng, Minhua Zhang, and Fanmei Meng

Subjects

Supercritical carbon dioxide, Chromatography, Materials science, Precipitation (chemistry), Applied Mathematics, General Chemical Engineering, Interface and colloid science, General Chemistry, Industrial and Manufacturing Engineering, Supercritical fluid, Chemical engineering, Phase (matter), Specific surface area, Porosity, Sol-gel

Abstract

Silica microspheres are of much interest in several areas, such as liquid chromatography, medicine, biochemistry, colloidal chemistry and aerosol research. In this study, the sol−gel method was used to prepare these microparticles followed by three different drying processes. The first process involved intermittent supercritical fluid drying (SCF-I) using intermittent supercritical carbon dioxide (scCO 2 ) at a low temperature. The second approach involved continuous supercritical fluid drying (SCF-C) using continuous scCO 2 at low temperature, as well. The third approach involved vacuum drying (WO), which is a high temperature process. All of the experiments led to the successful precipitation of silica microparticles in the micrometre range. In all of the cases, a spherical morphology and no agglomeration were observed. The optimum preparation conditions were determined as follows: stirring speed is 200 r/min; continuous phase/dispersed phase is 2/1; Span® 80/ Tween® 20 is 5/2; the ratio of surfactant is 17%. In addition, the primary textural characteristics of these microspheres were investigated by nitrogen physisorption experiments. The results indicated that the size of the pore volume is as follows: V SCF-C > V SCF-I > V WO . The BET data indicate that the specific surface area of the porous silica microspheres is as follows: S SCF-C > S SCF-I > S WO .

Published

2015

2. Influence of Supercritical CO2Pretreatment of Corn Stover with Ethanol-Water as Co-Solvent on Lignin Degradation

Author

Y. Sun, L. Yan, Zhongfeng Geng, M. Ren, Huisheng Lv, and M. Zhang

Subjects

Ethanol, General Chemical Engineering, fungi, technology, industry, and agriculture, food and beverages, Ether, macromolecular substances, General Chemistry, complex mixtures, Industrial and Manufacturing Engineering, Supercritical fluid, chemistry.chemical_compound, Corn stover, chemistry, Chemical engineering, Organic chemistry, Lignin, Fiber, Cellulose, Solubility

Abstract

The process of delignification during the pretreatment of corn stover in supercritical CO2 with ethanol-water as co-solvent was investigated. After pretreatment, many lignin droplets were found deposited on the fiber surface which hinder cellulose digestibility. These lignin droplets were removed by ethanol-water and after washing the optimal glucose yield increased significantly. Lignin degradation reactions competed with condensation reactions during pretreatment. The cleavage of ether bonds and the high solubility of lignin fragments in ethanol-water co-solvent were the key factors for lignin removal and degradation behavior during pretreatment.

Published

2013

3. Removal of Acetic Acid from Fuel Ethanol Using Ion-Exchange Resin

Author

Yanpeng Sun, Zhongfeng Geng, Minhua Zhang, Miaomiao Ren, and Huisheng Lv

Subjects

Ethanol, Chromatography, Fixed bed, General Chemical Engineering, technology, industry, and agriculture, Energy Engineering and Power Technology, Langmuir adsorption model, Atmospheric temperature range, Cylinder (engine), law.invention, Acetic acid, chemistry.chemical_compound, symbols.namesake, Fuel Technology, Adsorption, chemistry, Chemical engineering, law, symbols, Ion-exchange resin

Abstract

The amount of trace organic acids must be controlled in the fuel ethanol product in order to reduce the chance to corrode automotive cylinder. Ion-exchange resin was investigated to remove acids from fuel ethanol in this paper. Industrial resins, D301R, 330, 201×7, and D201, were selected as candidates, and a series of experiments were carried out to determine which one is the best. Acetic acid was employed as a simulated compound in these experiments for it is the main residual acid in fuel ethanol product. The results showed that the 330 resin was the most effective one to remove acid from fuel ethanol, and then, both static and dynamic experiments were carried out to evaluate the performance of the 330 resin. It was found that equilibrium data can be well described by Langmuir isotherm during the temperature range from 25 to 35 °C. The kinetic data fitted well with the pseudo-second-order kinetic model. Furthermore, a bench scale fixed bed was set up to determine the optimal adsorption and regeneration...

Published

2012

4. Removal of Acetic Acid from Fuel Ethanol Using Ion-Exchange Resin.

Author

Huisheng Lv, Yanpeng Sun, Minhua Zhang, Zhongfeng Geng, and Ren, Miaomiao

Published

2012