摘要
In this work,mass transfer mechanism was studied for 50%TBP( in kerosene) -phenol-water as the working system in different bydrophobic microporous hollow fiber modules. The effect of different operating conditions on the removal of phenol was aanlyzed. Solvent entraimment in this process was detected with MALVERN-2600 laser pellet diameter analytical equipment. Experimental reaults indicate the mass transfer coefficient is incressed while the two phase flow raten are inerassed. With incesses in the flow rate of the water phase,the removal ratio of phenol will be decreased. Highly effective removal of phenol could be reached by changing the experimental conditioms and the module configurstion. The solvent entraimment in the water phase in the mernbrane extraction process was found to be 5%-8% of that in conventional liquid-liquid extraction process. Thus,solvent pollution could be better controlled.
In this work, mass transfer mechanism was studied for 50%TBP (in kerosene)-phenol-water as the working system in different hydrophobic microporous hollow fiber modules. The effect of different operating conditions on the removal of phenol was analyzed. Solvent entrainment in this process was detected with MALVERN-2600 laser pellet diameter analytical equipment. Experimental results indicate the mass transfer coefficient is increased while the two phase flow rates are increased. With increases in the flow rate of the water phase, the removal ratio of phenol will be decreased. Highly effective removal of phenol could be reached by changing the experimental conditions and the module configuration. The solvent entrainment in the water phase in the membrane extraction process was found to be 5%—8% of that in conventional liquid-liquid extraction process. Thus, solvent pollution could be better controlled.
基金
Supported by the National Natural Science Foundation of China.
