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| ClassificationCode:TQ536,TQ536.1 |
| year,volume(issue):pagination: 2017,37(2):78-87 |
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Abstract: |
| The sol of the coal dense medium component which was produced by the extraction and stripping method was chosen as the coating solution. Through the filming and charring, it was successfully prepared as coal-based ceramics-carbon composite membranes. The carbonization conditions on the performance of the composite membrane prepared was studied, and the relationship between the carbonization process conditions and the composite membrane porosity, water permeability as well as rejection rate of the Fe(OH)3 colloidal and bovine serum albumin (BSA) sol was inspected. Then thermal evolution process and mechanism of the separation layer was discussed. The results show that: the heating rate, intermediate constant temperature, the intermediate holding time and final carbonization temperature in the carbonization process will affect the generation rate of the separation layer pyrolytic gas and liquid, as well as the state of adhering the solid becoming metaplast, thereby affect to the composite carbon membrane separation layer pore structure and distribution, and ultimately affect porosity, permeability and retention rate of the composite membrane; under the following carbonization process conditions: heating rate with 4 oC/min, intermediate constant temperature and time respectively at 460 oC and 20 min, final carbonization temperature at 600 oC, the composite membrane have better retention rate effect on Fe(OH)3 colloids; under the following carbonization process conditions: heating rate with 4 oC/min, intermediate constant temperature and time respectively at 490 oC and 20 min, final carbonization temperature at 800 oC, the composite membrane have better entrapped results on the BSA sol. The coal dense medium component major generates liquid and gas phase material in pyrolysis carbonization process due to its specific composite structure, and substantially no swelling effect in the process, this feature is very conducive to prepare composite membrane separation layer by the coal dense medium component. |
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Funds: |
| 国家自然科学基金(51274201、51674260);教育部高等学校博士学科点专项科研基金(20130095110006) |
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AuthorIntro: |
| 作者简介:秦志宏(1963-),男,安徽安庆人,博士,教授。从事煤转化技术方面研究。电话:13852034193, 邮箱 : qinzh1210@163.com |
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Reference: |
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