杨庆,沈新元,郯志清,郑红梅
YANG Qing 1,2, SHENG Xin-yuan1,2

• 1:东华大学纤维材料改性国家重点实验室
• 2:东华大学纤维材料改性国家重点实验室
• 3:东华大学纤维材料改性国家重点实验室
• 4:东华大学材料科学与工程学院 上海200051

摘要(Abstract)：

采用改变纺丝速度、拉伸工艺以及测试纤维内应力、声速值、强度值等方法对聚乙交酯(PGA)的纺丝加工工艺及纤维的力学性能进行了分析研究。结果表明:纺丝速度对PGA初生纤维的取向度几乎没有影响,后拉伸能有效提高纤维的取向度及强度。低速纺丝得到的初生纤维内应力较小,可以进行高倍后拉伸,而高速纺丝得到的初生纤维内应力较大,只能进行低倍后拉伸。适当的加温以及低速拉伸有利于得到较高强度的PGA纤维。总体来说,要得到具有较好力学性能的PGA纤维,必须采用低速纺丝、高倍后拉伸、低速拉伸相加的工艺路线。
The spinning technology for preparing PGA fiber was studied in this paper. The methods of measuring fiber internal stress, sonic velocity, tenacity and adjusting spinning speed, drawing temperature and rate were explored to analyses the mechanical properties of PGA fiber. The results showed that winding speed had little effect on the orientation degree of freshly spun fiber and it was the subsequent drawing that could effectively increase the fiber orientation degree. The freshly spun fiber with low internal stress spun at lower speed could be high drawn, while the freshly spun fiber spun at higher speed could only be drawn slightly due to its strong internal stress. Suitable drawing temperature and slow drawing rate were profitable for making PGA fiber with high tenacity. Generally speaking, PGA fiber with perfect mechanical performance could only be made by lower winding speed and higher post drawing as well as slow drawing rate.

关键词(KeyWords)： 聚乙交酯(PGA);纺丝工艺;纤维;力学性能
polyglycolic acid (PGA), spinning technology, fiber, mechanical properties

Abstract:

Keywords:

基金项目(Foundation):

作者(Author): 杨庆,沈新元,郯志清,郑红梅
YANG Qing 1,2, SHENG Xin-yuan1,2

参考文献(References)：

• [1]YukihitoS,HideyasuO,etal.Anewbioabsorbablesleeveforstaple-linereinforcement:reportofaclinicalexperience[J].SurgeryToday,2002,32:297-299.
• [2]KimBS,BaezCE,etal.Biomaterialsfortissueengineering[J].WorldJUrol,2000,18:2-9.
• [3]HardingSI,AfokeA,etal.Engineeringandcellattachmentproperties ofhumanfibronectin-fibrinogenscaffoldsforuseintissueengineered bloodvessels[J].BioprocessBiosystEng,2002,25:53-59.
• [4]SuzukiM,FukuharaK,etal.Simplifiedhepaticresectionutilizing absorbablepolyglycolicacid-basedtapeandotherligatureapparatus[J].JHepatobiliaryPancreatSurgery,1998,5:292-296.
• [5]BaykalA,OnatD,etal.Effectsofpolyglycolicacidandpolypropylene meshesonpostoperativeadhesionformationinmice[J].WorldJournalof Surgery,1997,21(6):579-583.
• [6]DesaiTA,DeutschJ,etal.Microtexturedcellcultureplatforms:biomimeticsubstratesforthegrowthofcardiacmyocytesandfibroblasts[J].BiomedicalMicrodevices,1999,2:123-129.
• [7]TuompoP,ArvelaV,etal.Osteochondritisdissecansofthekneefixed withbiodegradableself-reinforcedpolyglycolideandpolylactiderodsin24patients[J].InternationalOrthopaedics(SICOT),1997,21:355-360.
• [8]NordstromP,PohjonenT,etal.Shear-loadcarryingcapacitiesofthe distalratfemoraafterosteotomyfixedwithself-reinforcedpolyglycolic acidandpoly-L-lacticacidpins[J].JournalofMaterialsScience:MaterialsinMedicine,2002,13:65-68.
• [9]Vainionpaa,S.Biodegradationofpolyglycolicacidinbonetissue:An experimentalstudyonrabbits[J].ArchivesofOrthopaedicandTrauma Surgery,1986,104(6):333-338.
• [10]MuhonenJ,SuuronenR,etal.Effectofpolyglycolicacidmembrane onboneregenerationaroundtitaniumimplantsinsertedinbonesockets[J].JournalofMaterialsScience:MaterialsinMedicine,1994,5(1):40-42.
• [11]MorenoM,MagosFJ,etal.Comparisonoftheperformanceofthe GeaextracorporealknotwiththeRoederextracorporealknotandthe classicalknot[J].SurgicalEndoscopy,2004,18:157-160.
• [12]ZiabickiA著,孙君立,孙桐译.纤维成形基本原理.上海科学技术出版社,1983,213-216.
• [13]王华平,胡学超等.纺丝速度对涤纶FCY的无定形结构影响的研究[J].中国纺织大学学报,1998,24(3):14-19.
• [14]肖茹,顾莉琴等.纺丝速度和第三单体含量对CDP纤维超分子结构性能的影响[J].合成纤维工业,2002,25(4):13-15.
• [15]周正华.纺丝速度和定型温度对涤纶POY自伸长率的影响[J].合成技术及应用,2002,17(4):29-30.