高等学校化学学报
高等學校化學學報
고등학교화학학보
CHEMICAL JOURNAL OF CHINESE UNIVERSITIES
2014年
12期
2713-2719
,共7页
王海霞%刘明巧%崔建平%石海峰%齐鲁%王笃金
王海霞%劉明巧%崔建平%石海峰%齊魯%王篤金
왕해하%류명교%최건평%석해봉%제로%왕독금
纳米储能纤维%静电纺丝%水通量%聚偏氟乙烯%复合膜
納米儲能纖維%靜電紡絲%水通量%聚偏氟乙烯%複閤膜
납미저능섬유%정전방사%수통량%취편불을희%복합막
Energy-storage nanofiber%Electrospinning%Water flux%Poly ( vinylidene fluoride )%Composite membrane
以静电纺丝技术制备的同轴聚甲基丙烯酸十八烷基酯( PSMA)/聚对苯二甲酸乙二酯( PET)纳米储能纤维为支撑层,经聚偏氟乙烯( PVDF)涂覆成膜和溶剂化处理,制备了一种低压高水通量的纳米储能纤维复合过滤膜( NFCM),其中以水或乙醇为凝固溶液的复合过滤膜分别记为NFCM@H2 O或NFCM@EtOH.分析并讨论了不同溶剂处理方式对NFCM力学性能和表面形貌的影响,表征了膜的纯水通量和抗污性能,用扫描电子显微镜( SEM)观察了膜的横断面形貌.结果表明, PSMA/PET纳米储能纤维具有明显的吸放热行为,熔融温度和热焓值分别为36.5℃和10.7 J/g, NFCM的熔融温度和热焓值分别为36℃和2.7 J/g. NFCM的形貌结构、纯水通量和截留率与溶剂处理方式相关, NFCM@EtOH膜的水通量介于100~1400 L/( m2·h)之间,而NFCM@H2 O膜的水通量仅在40~220 L/( m2·h)之间. NFCM的拉伸强度由初始0.925 MPa( PVDF)提高到4.28 MPa以上. NFCM中的相变材料对膜过滤性能有重要影响,并在过滤温度低于50℃时具有减缓作用.
以靜電紡絲技術製備的同軸聚甲基丙烯痠十八烷基酯( PSMA)/聚對苯二甲痠乙二酯( PET)納米儲能纖維為支撐層,經聚偏氟乙烯( PVDF)塗覆成膜和溶劑化處理,製備瞭一種低壓高水通量的納米儲能纖維複閤過濾膜( NFCM),其中以水或乙醇為凝固溶液的複閤過濾膜分彆記為NFCM@H2 O或NFCM@EtOH.分析併討論瞭不同溶劑處理方式對NFCM力學性能和錶麵形貌的影響,錶徵瞭膜的純水通量和抗汙性能,用掃描電子顯微鏡( SEM)觀察瞭膜的橫斷麵形貌.結果錶明, PSMA/PET納米儲能纖維具有明顯的吸放熱行為,鎔融溫度和熱焓值分彆為36.5℃和10.7 J/g, NFCM的鎔融溫度和熱焓值分彆為36℃和2.7 J/g. NFCM的形貌結構、純水通量和截留率與溶劑處理方式相關, NFCM@EtOH膜的水通量介于100~1400 L/( m2·h)之間,而NFCM@H2 O膜的水通量僅在40~220 L/( m2·h)之間. NFCM的拉伸彊度由初始0.925 MPa( PVDF)提高到4.28 MPa以上. NFCM中的相變材料對膜過濾性能有重要影響,併在過濾溫度低于50℃時具有減緩作用.
이정전방사기술제비적동축취갑기병희산십팔완기지( PSMA)/취대분이갑산을이지( PET)납미저능섬유위지탱층,경취편불을희( PVDF)도복성막화용제화처리,제비료일충저압고수통량적납미저능섬유복합과려막( NFCM),기중이수혹을순위응고용액적복합과려막분별기위NFCM@H2 O혹NFCM@EtOH.분석병토론료불동용제처리방식대NFCM역학성능화표면형모적영향,표정료막적순수통량화항오성능,용소묘전자현미경( SEM)관찰료막적횡단면형모.결과표명, PSMA/PET납미저능섬유구유명현적흡방열행위,용융온도화열함치분별위36.5℃화10.7 J/g, NFCM적용융온도화열함치분별위36℃화2.7 J/g. NFCM적형모결구、순수통량화절류솔여용제처리방식상관, NFCM@EtOH막적수통량개우100~1400 L/( m2·h)지간,이NFCM@H2 O막적수통량부재40~220 L/( m2·h)지간. NFCM적랍신강도유초시0.925 MPa( PVDF)제고도4.28 MPa이상. NFCM중적상변재료대막과려성능유중요영향,병재과려온도저우50℃시구유감완작용.
Two type of composite membranes ( NFCM ) containing poly ( stearyl methacrylate ) ( PSMA )/poly( ethylene terephthalate) ( PET) nanofiber supporting layer, prepared by coaxial electrospinning technolo-gy, and poly( vinylidene fluoride) ( PVDF) substrate, were prepared using water or ethanol as the coagulation solution. NFCM has the low pressure and high water flux against the bulk PVDF membrane at the same condition. The morphological structure, the pure water flux and the rejection of NFCM show the strong dependence upon the solvent-treated process. The water flux of NFCM@EtOH is in the range from 100 to 1400 L/( m2 ·h);while for NFCM@H2 O, its water flux only is between 40 and 220 L/( m2 ·h) , indicating that EtOH shows the greatly influence on the surface porosity of membrane. The tensile strength of membrane changes from 0. 925 MPa of the original PVDF to 4. 28 MPa of NFCM, demonstrating that the incorporated nanofibers can effectively improve the mechanical property of PVDF membrane. Obvious thermal behaviour and the temperature buffering ability appear in NFCM, and it exhibits an active response when temperature is below 50 ℃. The slowdown amplitude of water flux with temperature is observed in NFCM as compared with the control. The prepared NFCM containing PSMA/PET nanofiber as the supporting layer provides a way to obtain the high-performance composite membrane with the high water flux.
