STUDIES ON THE CRIMP BEHAVIOR OF SIDE-BY-SIDE BICOMPONENT POLYAMIDE FIBERS

The supermolecular structure and mechanical properties as well as the crimp behavior of theside-by-side polyamide (PA 66-C710) fibers are studied by means of density gradient method,sonic measurement,X-ray,diffractometry,differential scanning calorimetry,crimp tester etc.fortheir as-spun fibers,drawn fibers,and boiling-water treated fibers.The effects of the processingand treatment conditions on the formation of the supermolecular structure and the crimp behaviorof the fibers are investigated and discussed in detail,also the crimp mechanism of the side-by-sidebicomponent fibers is proposed.From these results,it is shown that by adopting suitable spinningfinish,reasonable processing technology and optimal heat treatment conditions the side-by-sidebicomponent polyamide fibers with excellent crimp property,close to that of nylon texturizedstretch yarns,can be obtained.

Controllable large-scale processing of temperature regulating sheath-core fibers with high-enthalpy for thermal management

Temperature regulating fibers(TRF_(s)) with high enthalpy and high form stability are the key factors for thermal management. However, the enthalpies of most TRFsare not high, and the preparation methods are still at the laboratory scale. It remains a great challenge to use industrial spinning equipment to achieve continuous processing of TRF_(s) with excellent thermal and mechanical properties. Here, polyamide 6(PA6) based TRF_(s) with a sheath-core structure were prepared by bicomponent melt-spinning. The sheath-core TRF(TRF_(sc)) are composed of PA6 as sheath and functional PA6 as core, which are filled with the shape stable phase change materials(ssPCM),dendritic silica@polyethylene glycol(SiO_(2)@PEG). With the aid of the sheath structure, the filling content of SiO_(2)@PEG can reach 30 %, so that the enthalpy of the TRF_(s) can be as high as 21.3 J/g. The ultra-high enthalpy guarantees the temperature regulation ability during the alternating process of cooling and heating. In hot environment, the temperature regulation time is 6.59 min, and the temperature difference is 12.93℃. In addition, the mechanical strength of the prepared TRF_(sc) reaches 2.26 cN/dtex, which can fully meet its application in the field of thermal management textiles and devices to manage the temperature regulation of the human body or precision equipment, etc.

Silicon-Basing Ceramizable Composites Containing Long Fibers

Ceramization is a phenomenon which assures compactness of polymer-based composites in the case of their thermal degradation caused by open fire or exposure at high temperatures. This phenomenon is based on preventing volatiles of thermal decomposition of silicone rubber from evacuation by creation of ceramic layer. This ceramized structure is composed of mineral filer particles, connected by fluxing agent—glassy phase. The ceramic barrier created during firing is aimed to protect copper wire inside the cable from melting, being additionally strong enough to maintain integrity of electrical circuit. The paper presents experimental data on mechanical properties of silicone rubber composites strengthened additionally with long fibers of different types—aluminosilicate and polyamide (Kevlar) ones. Fibers were introduced into composites in oriented way. Mechanical properties were investigated taking into account fiber orientation anisotropy. Ceramization process of composites was described by observation of morphology and strengthen measurements of samples fired at 1000°C.

Characterization of Amino Terminated Hyperbranched Collagen Fiber and Adsorption Thermodynamics to Cr(Ⅵ)

In this study, a novel adsorption material amino terminated hyperbranched polyamide collagen fiber( CF-HBPN)was prepared by loading amino terminated hyperbranched polyamide( HBPN) which was synthesized by polycondensation of methacrylate and diethylenetriamine onto the surface of collagen fiber( CF) with glutaraldehyde as the cross-linking agent. X-ray photoelectron spectroscopy( XPS) and thermogravimetric analysis( TGA) were employed to characterize the structures of CF and CFHBPN. In addition,the adsorption property of CF-HBPN toward Cr( Ⅵ) and adsorption thermodynamic were studied as well. The experimental results indicated that the Cr( Ⅵ) 's removal rate by CF-HBPN was 3. 09 higher than that of CF under the same conditions. Langmuir single layer adsorption model was found more suitable to describe the adsorption process than Freundlich adsorption model. The adsorption process was an endothermic reaction. The adsorption efficiency was enhanced with the increase of temperature. X-ray diffraction( XRD) was employed to elucidate the difference between CF-HBPN and Cr( Ⅵ) loaded CF-HBPN[CF-HBPN-Cr( Ⅵ) ].

超声振动对玻璃纤维增强聚酰胺6注塑制件力学性能的影响

为提高纤维增强复合材料的力学性能,对玻璃纤维增强聚酰胺6(PA6/GF)复合材料进行了矩形平板制件超声辅助注射成型实验。通过对制件进行X射线衍射测试、扫描电子显微镜观测、傅里叶红外光谱分析以及拉伸性能测试,研究了超声施加时间和超声功率对制件的结晶度、玻璃纤维的取向程度、玻璃纤维与基体的结合强度以及制件力学性能的影响;并研究了经过超声振动的制件在吸水后其内部结晶度及力学性能的变化。结果表明,施加400 W超声振动,可以明显提高制件的结晶度;施加560 W超声时,玻璃纤维的取向形态得到改善,纤维与基体的结合强度有所提高,充填阶段施加超声所得制件的拉伸强度与弯曲强度比无超声振动的情形分别提高了11.9%与10.1%;但是如果继续增加超声功率,将会使制件的力学性能开始变差。制件吸水后,结晶度和力学性能下降,对制件的成型引入超声振动则能减小这种下降的幅度。

不同金属盐体系对锦纶66纤维结构与性能的影响

选用氯化钙、氯化锂、氯化铜及氯化锌四种金属盐,分别以去离子水和无水乙醇为溶剂配置成溶液,对锦纶66纤维进行络合改性处理,采用FTIR、DSC、XRD、SEM、单纤维拉伸研究不同金属盐及其溶剂种类对锦纶66纤维结构性能的影响。结果表明,经四种金属盐处理后,氯化铜对锦纶66纤维的结构性能影响最大、对纤维的络合作用最强,氯化锌对锦纶66纤维的结构、性能影响最小,氯化钙和氯化锂的影响程度居中,具体表现为红外光谱图中N-H振动峰向低波数移动,熔融温度下降、结晶度减小、拉伸断裂强度降低。选择氯化钙为金属盐络合剂时,以乙醇作为溶剂时对锦纶66纤维的结构、性能的影响作用大于以水为溶剂时,说明乙醇有利于金属离子与纤维之间形成络合作用。

碳纤维改性聚酰胺复合材料球拍制备及性能表征研究

乒乓球底板所使用的不同材料间性能差异较大,运动员可以根据自身的技术特长进行选择或个性化定制。文章以碳纤维及改性聚酰胺等为基础材料,经过复合加工制备了一种新型乒乓球拍,从该类型乒乓球底板特殊结构入手,对当前应用较多碳素球拍底板制备方法进行分析,通过与一般芳基纤维底板、玻璃纤维底板等的性能进行对比,总结出碳纤维复合材料乒乓球拍性能方面的优劣势。

静电纺聚酰胺6/聚苯乙烯复合纳米纤维膜制备及其空气过滤性能

针对空气过滤纤维材料的过滤效率、阻力和使用寿命难以平衡的问题,采用多喷头静电纺丝技术,制备了不同直径、形貌纤维及不同纤维沉积顺序的聚酰胺6/聚苯乙烯(PA6/PS)复合纳米纤维膜,测试了复合膜的平均孔径及孔隙率,建立了纤维结构与过滤效率及阻力的构效关系;结合扫描电镜表征探讨了不同形貌、直径纤维的叠加次序对过滤寿命及细颗粒物沉积行为的影响,系统研究了过滤风速、细颗粒物尺寸对过滤性能的影响。结果表明:在5.33 cm/s的风速下,以多喷头静电纺丝方式制备的PA6/PS复合膜具有更好的抵抗风速变化的能力,在长期使用中阻力增加较缓慢,其具有93.13%的过滤效率,30.67 Pa的过滤阻力和0.0889 Pa-1的品质因子,综合过滤性能优于同等条件下H10等级(过滤效率>90%)的商业玻璃纤维过滤膜。

PDA/Fe_(3)O_(4)上浆对碳纤维/聚酰胺6热塑性复合材料力学性能的影响

在碳纤维增强热塑性复合材料中,碳纤维(CF)与热塑性树脂基体间的界面强弱对其整体力学性能有巨大的影响。为改善CF与聚酰胺6(PA6)的界面性能,利用多巴胺(DA)的聚合与黏附特性,将纳米相四氧化三铁(Fe_(3)O_(4))引入到CF表面进行协同修饰,通过简单的浸渍共沉积,利用DA的氧化自聚合在CF表面构建聚多巴胺/纳米四氧化三铁(PDA/Fe_(3)O_(4))涂层。对CF改性前后表面微观结构与化学特性进行了表征,结果表明PDA/Fe_(3)O_(4)上浆剂能够显著提高CF表面的粗糙度与化学活性,加强纤维与树脂基体的机械啮合作用与化学相互作用。与未改性CF/PA6复合材料相比,制备得到的改性CF/PA6复合材料表现出优异的力学性能,其弯曲强度、层间剪切强度分别提高了30.8%和29.1%。

四缸发动机进气歧管热流道注射模设计

结合大型尺寸塑件发动机进气歧管批量生产需要,选用玻璃纤维增强聚酰胺专用塑料对其进行注射成型,材料中加纤质量分数为33%。模具使用一模一腔布局,模腔使用2个针阀式浇口进行浇注,相应的注塑工艺参数为模温70℃、注射压力100 MPa、充填时间5.5 s、保压压力50 MPa、保压时间11 s。针对塑件结构复杂、脱模困难问题,运用脱模方向集成设计方法设计了5个特殊脱模机构用于塑件的脱模;其中定模一侧布置3个联动式油缸驱动滑块斜抽芯机构,将斜向抽芯转化为水平侧抽芯,能有效减少斜抽芯机构件对模具厚度尺寸的要求;动模一侧布置的1个水平侧抽芯滑块机构和1个弯管抽芯机构,结合塑件弯管内壁的脱模采用分段抽芯脱模法进行设计,有效解决了塑件弯管内壁既有直线段又有弯管段而难以设计脱模机构的难题,保证了塑件自动化注塑生产的实现。结合弯管抽芯机构的动作需要,两板热流道模模架的开模由单次开模改进为两次开模,第二次开模使用油缸驱动动模板顶出而实现。塑件的顶出脱模借助两种油缸分两次实施顶出而实现。模具整体结构设计、机构配置合理,有较好的设计参考意义。

热塑性碳纤维/尼龙6复合材料界面优化及零件快速成型工艺研究

碳纤维复合材料具有质轻高强等优势,是绝佳的轻量化材料,但汽车常用的碳纤维复合材料以环氧树脂等热固性树脂为基体,大规模应用会面临不易回收的难题。热塑性碳纤维复合材料具有易回收的优势,但其如何提升碳纤维与热塑性树脂的界面结合力及零件成型效率是行业难题。本文以热塑性碳纤维/尼龙6复合材料为研究对象,针对商品化碳纤维/尼龙6界面相容性差的问题,创新设计一种新型的可溶性共聚酰胺上浆剂,将碳纤维/尼龙6的界面强度提升74.2%,显著提升了碳纤维/尼龙6的综合性能。同时,优化预浸料制备和连续模压成型的工艺参数,将碳纤维顶盖横梁的模压生产效率提升至3.4 min/件,满足汽车行业大批量产节拍要求。同时,碳纤维/尼龙6顶盖横梁具有极高的弯曲强度和模量,与钢制件相比轻量率达68.8%。综上,本文为热塑性碳纤维复合材料(易回收)在汽车上的批量化应用提供了创新解决方案。

玻纤增强PA6焊机外壳性能的影响因素数值模拟

深入探讨了玻璃纤维增强聚酰胺6在焊机外壳应用中的性能表现,并基于ANSYS软件平台,进行了静力学仿真和落球冲击仿真分析,旨在揭示玻纤含量、玻纤长径比以及玻纤取向等关键参数对焊机外壳性能的影响。静力学分析显示,当外壳承受2500 N的拉力时,玻纤含量的增加对焊机外壳应力强度的影响较小,但能够降低了外壳变形程度。当玻纤质量分数超过25%时,等效应力趋于稳定(约51 MPa)。此外,玻纤的取向对焊机外壳性能具有显著影响。当纤维沿X轴和Z轴取向且各占50%时(方向向量为a2),外壳的等效应力达54.6 MPa,同时变形量最小,仅为0.5 mm,这一性能与玻纤质量分数为40%的外壳相当。而玻纤长径比的增加对等效应力的影响并不显著,但有助于减少变形。进一步,通过落球冲击分析发现,随着玻纤含量的增加,外壳的等效应力逐渐增大,变形逐渐减小,这一趋势与静力学分析结果高度一致。当玻纤质量分数低于20%时,焊机外壳在冲击下易出现破裂;然而,当玻纤质量分数为20%~35%时,外壳表现出了优异的冲击性能,未出现开裂现象。

熔融法制备聚酰胺中空纤维膜的渗透汽化研究

为改善聚二甲基硅氧烷(PDMS)渗透汽化膜的力学性能,选用聚酰胺6(PA6)为基膜材料,乙烯-乙烯醇共聚物(EVOH)为致孔剂,通过熔融纺丝法制备PA6/EVOH中空纤维,并萃取除去EVOH得到PA6中空纤维膜。研究了EVOH含量对膜性能的影响,并在膜表面接枝聚二甲基硅氧烷(PDMS)测试PDMS接枝膜的渗透汽化性能。结果表明,PA6中空纤维膜的水通量随着EVOH含量的增加而增加,在0.05MPa压力下,水通量最大能可达到966.8L/(m^(2)·h),对碳素墨水(300nm)的截留率最大可达到80.2%,拉伸强度最大能达到12.4MPa。接枝PDMS的PA6中空纤维膜对乙醇溶液渗透通量为789.4g/(m^(2)·h),分离因子为8.15,为后续膜表面改性提供了思路。

Bio-based and Biodegradable Electrospun Fibers Composed of Poly(L-lactide) and Polyamide 4

Novel bio-based and biodegradable block copolymers were synthesized by "click" reaction between poly(L-lactide)(PLLA) and polyamide 4(PA4). Upon tuning the molar mass of PLLA block, the properties of copolymers and electrospun ultrafine fibers were investigated and compared with those of PLLA and PA4 blends. PLLA and PA4 were found incompatible and formed individual crystalline regions, along with reciprocal inhibition in crystallization. Electrospun fibers were highly hydrophobic, even if hydrophilic PA4 was the rich component. The crystallinity of either PLLA or PA4 decreased after electrospinning and PLLA-rich as-spun fibers were almost amorphous. Immersion tests proved that fibers of block copolymers were relatively homogeneous with micro-phase separation between PLLA and PA4. The fibrous structures of copolymers were different from those of the fibers electrospun from blends, for which sheath-core structure induced by macro-phase separation between homopolymers of PLLA and PA4 was confirmed by TEM, EDS, and XPS.

生物基PA56/512于GF/PA66复合材料轨道扣件的应用

采用熔融共混法制备了玻璃纤维(GF)/尼龙66(PA66)/生物基尼龙56/512(PA56/512)共聚物复合材料。考察了生物基PA56/512共聚物对复合材料综合性能的影响及其于轨道扣件产品应用效果。结果表明,PA56/512共聚物能明显改善复合材料的加工流动性能,促进GF的包覆及分散;提升复合材料的耐低温性能;解决GF/PA66复合材料吸水率偏高的问题。当PA56/512共聚物质量分数为20%时,复合材料的综合性能最佳。PA56/512共聚物的加入,提高了轨道扣件产品的绝缘性能、改善了制品外观,X射线测试结果表明,产品内部无气孔,满足轨道交通领域的应用要求。PA56/512共聚物的引入解决了传统尼龙复合材料吸水率高、强度与低温韧性无法兼顾问题,大幅拓宽了轨道扣件的应用范围。

聚酰胺酸大分子偶联剂乳液的合成及其在回收玻璃纤维增强高温尼龙的界面改性中的应用

为提升回收玻璃纤维(Recycled glass fiber,rGF)在增强高温尼龙复合材料中的应用价值,制备用于rGF表面处理的耐高温型玻璃纤维浸润剂。以4,4′-联苯醚二酐(ODPA)为二酸酐单体、4,4′-二氨基二苯醚(ODA)为二胺单体,合成聚酰胺酸(PAA),然后与γ-氨丙基三乙氧基硅烷(KH550)反应得到聚酰胺酸大分子偶联剂(PAA-KH550);通过调控ODPA与ODA单体比例,制备得到稳定分散的自乳化PAA-KH550乳液。通过激光粒度分析仪、傅里叶变换红外光谱仪及热失重分析仪对乳液的粒径、化学结构及PAA-KH550乳液固化膜的耐高温性能进行测试;并采用扫描电子显微镜、单纤维强力机、全自动表面张力仪及复合材料界面评价装置对乳液涂覆的GF进行形貌观察、单丝性能测试、浸润性测试及与聚酰胺46(PA46)的界面剪切强度测试。结果表明:乳液平均粒径均为110~125 nm,且粒径分布较小;PAA-KH550乳液固化膜耐高温性能优于PAA乳液固化膜,其5%热分解温度(T_(d5))在350℃以上;制得的乳液能在rGF表面均匀成膜,有效弥补纤维表面缺陷,从而提升rGF的力学性能。此外,乳液涂敷固化后在纤维表面形成的涂层可有效提高纤维表面能,有助于改善GF与PA46的界面结合性能;实验测得经PAA-KH550乳液处理的GF/PA46复合材料的界面剪切强度(IFSS)最高达到(31.29±6.39)MPa,相比未经乳液处理的样品提高了37%。制备的水体系分散稳定的PAA乳液和PAA-KH550乳液,将其应用于rGF表面可有效恢复rGF的综合性能,同时可改善与PA46的界面结合,提高rGF/PA46复合材料的耐高温性能及力学性能,为rGF在高性能复合材料中的应用提供了新方案。

芳香族聚酰胺材料:从一维到二维

芳香族聚酰胺产品(如芳纶系列产品)因其综合性能优异而应用广泛。近几年,国内外研究者对其合成方法的研究取得了一系列原创性进展,但是国内文献仍然缺乏对这些成果的综述,特别是从材料维度的角度进行评述。对一维和二维芳香族聚酰胺材料取得的最新进展进行分类介绍,总结了各类合成方法的特点及其应用前景,并对芳香族聚酰胺的合成方法进行了简要展望。

熔体直纺缝纫线用PA 66纤维生产工艺探讨

以质量分数为48.9%的尼龙66(PA 66)盐液为原料,采用连续聚合-熔体直纺工艺路线,在常规生产线上生产122 dtex/36 f缝纫线用PA 66纤维,重点讨论熔体黏度、缓冷器温度、侧吹风条件、上油率、拉伸倍数、热定形温度等对生产及产品质量的影响。结果表明:控制PA 66熔体相对黏度(83.0±2),缓冷器温度(285±2)℃,侧吹风速度0.2~0.3 m/s、温度22℃,纤维上油率(0.4±0.1)%,拉伸倍数(5.5±0.1),热定形温度(230±2)℃,生产过程稳定,可纺性好;在上述工艺条件下,生产的122 dtex/36 f缝纫线用PA 66纤维A级品率达88%以上,纤维断裂强度高达8.2 cN/dtex,干热收缩率低至3.9%,染色均匀度为3~4级,可满足缝纫线客户的用丝要求。

阻燃抗熔滴PA 6膨体长丝的制备及其性能研究

采用自制的阻燃抗熔滴母粒与聚酰胺6(PA 6)切片共混,通过熔融纺丝-拉伸-变形一步法制备阻燃抗熔滴PA 6膨体长丝,重点研究母粒含量对纤维阻燃抗熔滴性能的影响,并对纤维形貌、力学性能、热收缩性能和结晶性能进行表征。结果表明:阻燃抗熔滴PA 6膨体长丝单纤维直径约50μm,截面为弧边三角形,随着母粒含量的增加,纤维的变形蓬松效果变差;随着母粒含量的增加,阻燃抗熔滴PA 6膨体长丝的极限氧指数(LOI)增加,母粒质量分数为7.5%时纤维LOI达29%,母粒质量分数为10.0%时纤维LOI达33%,且抗熔滴性好;随着母粒含量的增加,阻燃抗熔滴PA 6膨体长丝的断裂强度变化不大,约2.60 cN/dtex,母粒质量分数为7.5%时纤维综合力学性能最好;随着母粒含量的增加,阻燃抗熔滴PA 6膨体长丝的沸水收缩率降低,玻璃化转变温度、熔程先降低后升高,熔融峰顶温度、熔融热焓、结晶度先升高后降低;综合考虑纤维的阻燃抗熔滴性及力学性能,同时兼顾纤维的蓬松性,制备阻燃抗熔滴PA 6膨体长丝时添加阻燃抗熔滴母粒质量分数为7.5%较合适。

锦纶6/涤纶皮芯复合纤维定性鉴别方法研究

锦纶6/涤纶皮芯复合纤维是一种新型纤维,在现有的纤维定性鉴别体系中暂无有效的鉴别方法。本文采用熔点法快速剥离皮层纤维,同时结合传统显微镜法和溶解法建立了一种操作简便、高效的锦纶6/涤纶皮芯复合纤维定性鉴别方法。该鉴别方法操作简单、成本低、不需使用大型设备,可有效鉴别锦纶6/涤纶皮芯复合纤维并可应用于类似复合纤维的鉴别中。