成形条件对PAN原丝微孔结构及热性能的影响

将不同浓度的聚丙烯腈(PAN)原液在不同凝固浴温度下进行湿法纺丝,制得PAN原丝,再将PAN原丝在沸水浴中进行5倍拉伸。探讨了成形条件以及拉伸对PAN原丝微孔结构及热性能的影响。结果表明:当PAN纺丝原液质量分数为22%,凝固浴温度为10℃时,可以得到结构均匀致密的PAN原丝。PAN原丝经5倍拉伸后热分解温度降低,残留量减小。     

PAN原丝成形过程中孔隙结构的形成和演变

采用干湿法纺丝在梯级凝固成形条件和后续工艺下得到聚丙烯腈(PAN)原丝,利用扫描电镜、氮气吸附等方法测试研究了PAN原丝中孔隙的形成和演变。结果表明:在凝固成形阶段,PAN原丝内孔隙的形成是溶剂和非溶剂双扩散及PAN相分离双重作用的结果;PAN原丝经过沸水拉伸、干燥致密化、饱和蒸汽拉伸和热定型等处理,其纤维密度、结晶度增大,力学性能提高,其孔隙平均孔径、孔隙体积和孔隙含量均逐渐减小;PAN原丝内闭合孔隙经过拉伸后会形成新的开放孔隙,开放孔隙在干燥致密化后闭合和消失。     

干湿纺中聚丙烯腈原丝凝固成形的探讨

介绍了聚丙烯腈（PAN）碳纤维原丝在以温度为主导的热致变和浓度为主导的双扩散致变下的成形过程,分析了凝固pH及牵伸率等对凝固成形的影响,并对干湿纺下淬火成膜,膜内液滴变化、细颈区拉伸等作出新的解释,从而对干湿纺下凝固成形的机理有一定的宏观把握,为纺出高品质的PAN原丝奠定理论基础.     

湿纺工艺纺制PAN中空纤维成形机理研究

利用C型喷丝板进行挤出凝固,采用湿法纺丝工艺制备聚丙烯腈(PAN)中空纤维,从PAN/二甲基亚砜(DMSO)纺丝原液的流变性能和凝固过程的相分离两个方面探讨了PAN中空纤维的成形机理。结果表明:纺丝液随剪切速率(γ)的增加逐渐发生由粘性向弹性的转变是挤出胀大的主要原因,其粘弹转变点随着温度的升高而向高γ移动,在60℃下的纺丝液弧片接触成孔的理论临界γ为212 s~(-1);纺丝液在凝固浴中表层成膜是PAN-DMSO-H_2O三元体系相分离的结果,纺丝液细流表面成膜速度是影响孔结构闭合的重要因素,可以通过凝固浴浓度和凝固浴调节剂来控制。     

凝固条件对PAN初生纤维微结构的影响

通过湿法纺丝工艺制备聚丙烯腈(PAN)初生纤维,借助于X射线衍射仪、声速仪、扫描电子显微镜、小角X光散射仪等,研究了凝固浴温度、凝固浴浓度、喷丝头拉伸等凝固条件对初生纤维晶态结构、取向结构、形态结构的影响。结果表明:PAN纤维的凝聚态结构和形态结构在初生纤维形成时已基本形成;PAN初生纤维的结晶度达40%以上,其结晶度和结晶尺寸受凝固浴温度和浓度的影响;PAN初生纤维和原丝的晶区取向和全取向随着喷丝头拉伸的增大而增大;PAN初生纤维具有沿纤维轴向高度取向的沟槽,通过改变成形条件,可以获得沟槽浅且规整性完美的纤维表面;提高凝固浴浓度,可以形成结构均质、致密的PAN初生纤维,避免皮芯结构及芯部出现较多孔洞。     

凝固浴对PAN原丝性能的影响

在生产聚丙烯腈(PAN)炭纤维过程中,纺丝期间凝固浴的各种条件对纤维的成型和性能起着关键作用。本文介绍PAN高聚物在湿法一步法纺丝过程中二甲基亚砜(DMSO)凝固浴各种成型工艺条件对PAN原丝的结构、机械和物理性能的影响。     

PAN原丝成形工艺与碳纤维晶体结构和性能的关联性研究

采用广角X射线衍射方法对不同成形工艺的PAN原丝与碳纤维晶体结构和性能的关联性进行了实验和分析。研究表明:PAN原丝的晶体结构与凝固浴成形和纺丝牵伸工艺有直接关联性,由干喷湿纺成形和高倍纺丝牵伸制备的原丝具有晶粒尺寸较大、晶面间距较小和结晶度较高的特点。干喷湿纺成形工艺制备的原丝在碳化过程中石墨晶体的生长速率大于湿法纺丝,且原丝的PAN准晶体结构对碳纤维乱层石墨晶体结构具有遗传型。干喷湿纺成形和高倍数纺丝牵伸更容易获得兼具较高拉伸强度和较高拉伸模量的碳纤维。     

聚丙烯腈基碳纤维纺丝过程中的取向性研究

以聚丙烯腈(PAN)为原料,二甲基亚砜(DMSO)为溶剂,通过干喷湿纺工艺制备PAN基碳纤维原丝,采用X射线衍射仪对纺丝过程中不同工艺阶段纤维微晶进行测试,研究PAN纤维在纺丝过程中密度和微观结构的变化.结果表明,在纺丝过程中PAN纤维通过凝固浴、水洗、沸水牵伸、致密化、蒸汽牵伸和热定型工艺,纤维的密度增大、线密度逐步...     

聚丙烯腈原丝及其干喷湿纺

介绍了用于 PAN基碳纤维的聚丙烯腈原丝的发展历史 ,阐述了聚丙烯腈纺丝工艺中的主要工序和技术关键 ,指出了可以在聚合、纺丝过程中通过控制杂质及使用高相对分子质量的 PAN树脂纺制 PAN纤维等方法来提高原丝的性能。着重介绍了目前纺丝工艺中 PAN共聚体的制备、纺丝流体的流变行为及其凝固过程等重要工序的研究成果     

氨化对PAN原丝结构性能的影响

在聚丙烯腈(PAN)原丝湿法纺丝生产过程中,以二甲基亚砜/水(DMSO/H_2O)为凝固体系,在DMSO质量分数为72%,温度为52℃的凝固浴中通过流量计定量加入氨,以凝固浴溶液的pH值衡量氨化量的大小,研究了不同pH值对PAN原丝结构、性能及可纺性的影响。结果表明:在凝固浴溶液的pH值为8.6~10.0时,PAN原丝径向形态由腰形变成腰圆形,最后变成圆形;随着凝固浴溶液pH值的升高,PAN原丝的结晶度先升高后下降,膨润度则先降低后升高,直径不均率下降,强力不均率先下降后升高;凝固浴溶液pH值为9.5时,PAN原丝的结晶度最高,膨润度最小,直径不均率和强力不均率最低,可纺性最好,最终PAN基碳纤维的强度最高为3.83 GPa。     

聚丙烯腈原丝毛丝形成与控制工艺研究

从纺丝生产工艺方面对聚丙烯腈(PAN)原丝毛丝形成的因素和控制进行了试验。研究表明:纺丝液应反应程度均一,有适宜的PAN相对分子质量和较窄的分布,并须经严格的脱单、脱泡及分级过滤;较缓的凝固过程和合理匹配凝固浴浓度、温度、循环量并辅以氨化处理等工艺优化;合理的水洗工艺可有效降低二甲基亚砜(DMSO)的残余质量分数;优质的油剂和合理的上油工艺;合理的干燥致密化工艺;分段牵伸,总牵伸倍数的控制等工艺优化,可有效避免和控制原丝制备过程中毛丝的形成。     

Phase Diagram for Liquid Crystalline Polymer/ Polycarbonate Blends

A novel mechanism to form binary polymer blends is through phase separation by spinodal decomposition in the unstable region of the phase diagram. The present work investigates the effects of thermally‐induced phase separation by spinodal decomposition on the morphology development of liquid crystalline polymer/polycarbonate blends. Moreover, a thermodynamic binary phase diagram is obtained using a twin‐screw extruder at various processing melt temperatures. Differential scanning calorimetry and scanning electron microscopy were used to study the miscibility of the blends and the resulting morphology. A thermodynamic binary phase diagram exhibiting a lower critical solution temperature was obtained. The droplet size distribution of the blend was also obtained and discussed in light of the Cahn‐Hilliard theory.     

The index of dry‐jet wet spinning for polyacrylonitrile precursor fibers

A new spinning index for a PAN precursor fiber is proposed that includes the viscosity of a spinning dope, the thermodynamic affinity, and the draw ratio during the spinning process. Through dry‐jet wet spinning, six types of PAN precursor fibers with different spinning parameters, including solid content, solvent content in a bath, and draw ratio, were fabricated and analyzed with tensile tests, SEM, and XRD. The results show that the spinning index can reflect the mechanical properties of the fibers but is less indicative of crystallinity. Hence, the current spinning index is recommended for use as an indicator for the mechanical properties of PAN precursor fibers. © 2014 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2015 , 132, 41265.     

Thermodynamic study of non-solvent/dimethyl sulfoxide/polyacrylonitrile ternary systems: effects of the non-solvent species

In order to investigate the effects of the non-solvent species on the formation mechanism of polyacrylonitrile (PAN) fiber in wet spinning, theoretical ternary phase diagrams of water/DMSO/PAN and ethanol/DMSO/PAN systems were constructed based on the extended Flory–Huggins theory. The cloud-points of dilute PAN solutions of the two systems were determined by titration method and those of concentrated PAN solutions from Boom’s linearized cloud-point correlation. Binary interaction parameters were calculated and optimized to construct the theoretical phase diagram. The obtained diagrams were used to investigate the effects of the non-solvent species on the formation of PAN fibers. If the non-solvent water is replaced with ethanol, the meta-stable two-phase region in the ternary phase diagram increases. This favors the de-mixing of the filament via nucleation and growth mechanism during the coagulation process, resulting in homogenous dense PAN fibers with low porosity.     

PVDF porous matrix with controlled microstructure prepared by TIPS process as polymer electrolyte for lithium ion battery

Poly(vinylidene fluoride) (PVDF) microporous matrix of polymer electrolyte for lithium ion battery was prepared via the thermally induced phase separation (TIPS) process using diluent mixture of dibutyl phthalate (DBP) and di(2-ethylhexyl) phthalate (DEHP). Since this method has only one parameter, namely the DBP/DEHP ratio in diluent mixture, the membrane microstructure is easily and conveniently controlled. With the assistance of a pseudo-binary temperature-DBP ratio phase diagram of the PVDF-diluent mixture system, the membrane formation mechanism for different microstructures of membranes was proposed. In addition to studying the different microstructures available in TIPS process, the relationship between performance of membrane, electrochemical property of polymer electrolyte and final microstructure has been investigated in this paper.     

超高分子量聚乙烯微孔材料微观结构形成机理的研究 (I)相分离过程对微观结构的影响

超高分子量聚乙烯（ＵＨＭＷＰＥ）微孔材料是以ＵＨＭＷＰＥ为聚合物基体的一种新型功能性材料,利用这种材料能够实现非均相分离、过滤及离子通透等多种单元操作过程,可广泛地应用于化工、医药、能源等领域［１］。针对ＵＨＭＷＰＥ物料的特殊性能,采用热致相分离方法［２］（ＴＩＰＳ）进行微孔材料的成型。ＴＩＰＳ过程涉及到聚合物－溶剂二元体系,因此对ＴＩＰＳ的二元体系热力学过程进行了研究。同时,二元体系的相分离过程对微观结构有很大影响。结合ＵＨＭＷＰＥ－石蜡油二元体系相图可以知道,该二元体系的相分离由两种不同的相分离过程组成———固液相分离和液液相分离,研究了两种分离过程对最终微观结构的影响。