天津工业大学学报
天津工業大學學報
천진공업대학학보
JOURNAL OF TIANJIN POLYTECHNIC UNIVERSITY
2015年
2期
11-15
,共5页
王春红%贺文婷%王莹%李康
王春紅%賀文婷%王瑩%李康
왕춘홍%하문정%왕형%리강
石墨%聚乙烯醇%纳米纤维膜%热稳定性%电导率
石墨%聚乙烯醇%納米纖維膜%熱穩定性%電導率
석묵%취을희순%납미섬유막%열은정성%전도솔
graphite%poly(vinyl alcohol)%nano fiber membrane%thermal stability%electrical conductivity
应用静电纺丝技术制备石墨/聚乙烯醇(PVA)纳米纤维,并将该复合纤维收集成无纺布薄膜;采用扫描电子显微镜(SEM)观察了复合纤维的微观形貌和结构,利用宽频质谱仪测试了纤维的导电性,利用万能强力机测试了不同纳米石墨含量纤维薄膜的拉伸力学性能,并利用X射线衍射仪(XRD)和热重分析仪(TG)测试了复合纤维的物相及热力学行为.结果表明:在聚乙烯醇质量分数为8%、石墨质量分数为4%时,所制备的纳米纤维膜导电性最高,且力学性能最好,与纯PVA相比,电导率和断裂强度分别提高1个数量级和127.33%;XRD测试结果表明,纳米石墨成功附着在PVA中;TG结果表明,石墨/PVA复合纤维初始分解温度相对于纯PVA变化不大,当样品质量保持率为40%时,4%石墨/PVA复合纤维较纯PVA相比,其分解温度提高了35℃.
應用靜電紡絲技術製備石墨/聚乙烯醇(PVA)納米纖維,併將該複閤纖維收集成無紡佈薄膜;採用掃描電子顯微鏡(SEM)觀察瞭複閤纖維的微觀形貌和結構,利用寬頻質譜儀測試瞭纖維的導電性,利用萬能彊力機測試瞭不同納米石墨含量纖維薄膜的拉伸力學性能,併利用X射線衍射儀(XRD)和熱重分析儀(TG)測試瞭複閤纖維的物相及熱力學行為.結果錶明:在聚乙烯醇質量分數為8%、石墨質量分數為4%時,所製備的納米纖維膜導電性最高,且力學性能最好,與純PVA相比,電導率和斷裂彊度分彆提高1箇數量級和127.33%;XRD測試結果錶明,納米石墨成功附著在PVA中;TG結果錶明,石墨/PVA複閤纖維初始分解溫度相對于純PVA變化不大,噹樣品質量保持率為40%時,4%石墨/PVA複閤纖維較純PVA相比,其分解溫度提高瞭35℃.
응용정전방사기술제비석묵/취을희순(PVA)납미섬유,병장해복합섬유수집성무방포박막;채용소묘전자현미경(SEM)관찰료복합섬유적미관형모화결구,이용관빈질보의측시료섬유적도전성,이용만능강력궤측시료불동납미석묵함량섬유박막적랍신역학성능,병이용X사선연사의(XRD)화열중분석의(TG)측시료복합섬유적물상급열역학행위.결과표명:재취을희순질량분수위8%、석묵질량분수위4%시,소제비적납미섬유막도전성최고,차역학성능최호,여순PVA상비,전도솔화단렬강도분별제고1개수량급화127.33%;XRD측시결과표명,납미석묵성공부착재PVA중;TG결과표명,석묵/PVA복합섬유초시분해온도상대우순PVA변화불대,당양품질량보지솔위40%시,4%석묵/PVA복합섬유교순PVA상비,기분해온도제고료35℃.
The electrospinning technology was used to produce graphite/poly (vinyl alcohol) (PVA) composite nanofibers. SEM was used to investigate fiber microstructure, broadband dielectric spectrometer was used to investigate the conductivity, all purpose strength tester was used to test the tensile strength of nanofiber membrane with different graphite contents; and XRD and TGA were used to investigate the phase and thermal properties. The results revealed that the conductivity and tensile strength of the nanofiber membrane reached the highest with 8%!PVA and 4%!graphite, increased by one order of magnitude and 127.33%!respectively. The inclusion of nanographite in the nanocomposite fibers is confirmed by XRD. The TG results showed that compared with PVA nanofibers, the initial heat decomposition temperature of graphite/PVA composite nanofibers had little change, but when the weight percentage was 40%, the heat decomposition temperature of composite nanofibers with 4%! graphite increased by 35℃.
