化工学报
化工學報
화공학보
JOURNAL OF CHEMICAL INDUSY AND ENGINEERING (CHINA)
2014年
5期
1743-1749
,共7页
刘煌%吴雨晴%陈光进%刘蓓%杨兰英%潘勇
劉煌%吳雨晴%陳光進%劉蓓%楊蘭英%潘勇
류황%오우청%진광진%류배%양란영%반용
沼气%油-水乳液%耦合分离%水合物
沼氣%油-水乳液%耦閤分離%水閤物
소기%유-수유액%우합분리%수합물
biogas%oil-water emulsion%hybrid separation%hydrate
研究了柴油-水乳液体系在水合物生成条件下对沼气(CO2/CH4)中 CO2的捕集能力。阻聚剂Span20被加入到乳液中以分散水滴和水合物颗粒。综合考虑了温度、原料气组成、压力和乳液含水率对柴油-水乳液体系分离能力的影响。从实验结果可以看出,吸收-水合耦合分离效果明显优于单独的吸收分离,且分离平衡后,浆液中水合物分散均匀,流动性良好。乳液体系分离能力在一定范围内随着温度降低和含水率的增加而增强。综合考虑乳液分离能力和流动特性表明,温度270.15~272.15 K,体系含水率20%~25%(vol)和初始推动力为3.2 MPa左右时为最合适的分离条件,在对应条件下经过两级模拟分离,气相中CO2浓度能从31%(mol)降到近10%(mol),超过87%(mol)的CO2被水合物浆液捕集。
研究瞭柴油-水乳液體繫在水閤物生成條件下對沼氣(CO2/CH4)中 CO2的捕集能力。阻聚劑Span20被加入到乳液中以分散水滴和水閤物顆粒。綜閤攷慮瞭溫度、原料氣組成、壓力和乳液含水率對柴油-水乳液體繫分離能力的影響。從實驗結果可以看齣,吸收-水閤耦閤分離效果明顯優于單獨的吸收分離,且分離平衡後,漿液中水閤物分散均勻,流動性良好。乳液體繫分離能力在一定範圍內隨著溫度降低和含水率的增加而增彊。綜閤攷慮乳液分離能力和流動特性錶明,溫度270.15~272.15 K,體繫含水率20%~25%(vol)和初始推動力為3.2 MPa左右時為最閤適的分離條件,在對應條件下經過兩級模擬分離,氣相中CO2濃度能從31%(mol)降到近10%(mol),超過87%(mol)的CO2被水閤物漿液捕集。
연구료시유-수유액체계재수합물생성조건하대소기(CO2/CH4)중 CO2적포집능력。조취제Span20피가입도유액중이분산수적화수합물과립。종합고필료온도、원료기조성、압력화유액함수솔대시유-수유액체계분리능력적영향。종실험결과가이간출,흡수-수합우합분리효과명현우우단독적흡수분리,차분리평형후,장액중수합물분산균균,류동성량호。유액체계분리능력재일정범위내수착온도강저화함수솔적증가이증강。종합고필유액분리능력화류동특성표명,온도270.15~272.15 K,체계함수솔20%~25%(vol)화초시추동력위3.2 MPa좌우시위최합괄적분리조건,재대응조건하경과량급모의분리,기상중CO2농도능종31%(mol)강도근10%(mol),초과87%(mol)적CO2피수합물장액포집。
Water in oil emulsion was used to capture CO2 from biogas (CO2/CH4) under hydrate formation condition. Span 20 was used to disperse aqueous phase or hydrate in oil phase. The influences of temperature, feed gas composition, pressure and water cut on the separation efficiency of emulsion were investigated. The separation ability of the absorption-hydration hybrid method was much better than that of the single absorption separation method, and uniform and flowable hydrate slurry could be obtained. The separation ability of the emulsion system increased with decreasing temperature or increasing water cut in specific ranges. Taking into account both separation efficiency and flowability of the slurry, the suitable operation temperature, pressure and water cut were determined as 270.15-272.15 K, around 3.2 MPa and 20%-25%(vol), respectively. Under these conditions, after a two-stage separation, the content of CO2 in vapor phase could be reduced from 31%(mol) to nearly 10%(mol), more than 87%(mol) CO2 could be captured by the slurry.
