STRUCTURE EVOLUTION OF POLYMER CHAINS FOR NECKING FORMATION IN HIGH-SPEED FIBER SPINNING PROCESS

Finite element method is used to simulate the high-speed melt spinning process, based on the equation system proposed by Doufas et al. Calculation predicts a neck-like deformation, as well as the related profiles of velocity, diameter, temperature, chain orientation, and crystallinity in the fiber spinning process. Considering combined effects on the process such as flow-induced crystallization, viscoelasticity, filament cooling, air drag, inertia, surface tension and gravity, the simulated material flow behaviors are consistent with those observed for semi-crystalline polymers under various spinning conditions, The structure change of polymer coils in the necking region described by the evolution of conformation tensor is also investigated. Based on the relaxation mechanism of macromolecules in flow field different types of morphology change of polymer chains before and in the neck are proposed, giving a complete prospect of structure evolution and crystallization of semi-crystalline polymer in the high speed fiber spinning process.

Platinum/rhodium Alloy Bushing for Drawing Glass Fibers in Centrifugal-spinneret-blow Process

In this paper,glass fibers were prepared by centrifugal-spinneret-blow(CSB) process.The molten glass got different flow rate from 390 kg/h to 270 kg/h by adjusting the electric current of platinum/10 rhodium alloy bushing.The diameter and microstructure of glass fibers have been investigated by scanning electron microscopy(SEM) and vertical optical microscope(VOM).The results indicated that the flow rate of molten glass was proportional to the diameter of glass fibers when the molten glass got main flow rate of 330 kg/h.The lower the flow rate was,the finer the average diameter was.

Energy Saving in Construction by Wide Application of High-Quality Insulation Based on Basalt Fibers

The influence of modern heat insulation materials on the ecological compatibility and fire resistance of residential and public buildings is considered. The nomenclature of fibrous heat insulation materials from basic rocks of volcanic origin is described. For basalt super thin fibers (BSTF), the production technology is described. The factors negatively influencing the engineering-and-economical performance of the duplex technology of production of the BSTF are analyzed. The engineering-and-economical performance of innovative enterprises for the production of basalt heat insulation and measures for its use in construction are given.

Watt-level Yb-doped silica glass fiber laser with a core made by sol-gel method

A Yb-doped silica glass fiber laser with a core made by sol-gel method is reported. The maximum power of 1.14 W is obtained with a pump power of 5.46 W at a wavelength of 976 nm. The slope efficiency is 34%. The refractive index fluctuation across the core is below 5×10^-4 at a doping level of Yb 0.15 mol%, A203 4.0 mol%, and P2O5 2.0 mol%. High background attenuation of 6 dB/m at 1 053 nm limites the slope efficiency and maximum output power.

Effects of Process Technology on Structure and Properties of HMLS Fibers

High modulus low shrinkage (HMLS) fibers have been prepared by using higher viscosity PET chips. The effects of the process conditions on their structure and properties have been studied by various testing techniques. The results show that the suitable spinning speed for preparing of HMLS fibers is 2 000 ～ 2 800 m/min. With the increase of the spinning speed, the density, crystallinity, and birefringence of the initial fibers increase obviously, but the shrinkage ratio decreases rapidly. The effects of process technology on properties of the HMLS fibers have also been discussed.

THERMAL DEGRADATION AND FLAME RETARDANCY OF CALCIUM ALGINATE FIBERS

Calcium alginate fibers were prepared by wet spinning of sodium alginate into a coagulating bath containing calcium chloride.The thermal degradation and flame retardancy of calcium alginate fibers were investigated with thermal gravimetry(TG),X-ray diffraction(XRD),limiting oxygen index(LOI) and cone calorimeter(CONE).The results show that calcium alginate fibers are inherently flame retardant with a LOI value of 34,and the heat release rate(HRR),total heat release(THR),CO and CO_2 concentrations during com...

Flow and Heat Transfer of Basalt Melt in the Feeder of the Smelter Furnace

The flow and heat transfer of the basalt melt in the boundary layer on a flat plate is considered. The conditions of formation of the layer and the intensity of heat transfer are determined. A self-similar analysis using the symmetry method was used. A system of ordinary differential equations in self-similar form is obtained. The fluid flow and heat transfer of molten basalt at a laminar steady-state flow in the feeder furnaces are numerically researched. The term “protective layer” on the interface “basalt melt-lining” is introduced. The dependences for the calculation of dimensionless shear stresses and the Nusselt number on the lining surface are obtained. The conditions of rational organization of the technological process of basalt melt feeding in the furnace feeder are formulated.

复合绝缘材料用连续玄武岩纤维老化特性及机理

探究连续玄武岩纤维在各类介质环境下的稳定性对于拓展其在复合绝缘材料上的应用至关重要。为此,文中比对了10组不同产地的连续玄武岩纤维与无碱玻璃纤维在酸性环境、碱性环境、富盐环境以及高温富盐环境下的老化特征差异,分析了连续玄武岩纤维的老化机理,通过灰色关联分析明确了构成玄武岩纤维耐候性的关键成分。结果表明:超过50%的玄武岩纤维样本拥有优于无碱玻璃纤维的耐盐碱环境的能力;碱性环境下,Si、Al、B元素与OH−的反应性造成两类纤维损伤,其中玄纤由于内部高含量的Ca、Mg,更易形成氢氧化物附着于纤维表面,降低了损伤程度;富盐环境下纤维表层的Ca、Na、K等元素扩散至溶液,导致了纤维表层结构疏松,且在介质渗透溶胀的作用下形成缺陷,致使两类纤维强度同步下降,但在老化周期内玄武岩纤维仍呈现出更高的力学特征。综上,玄武岩纤维更适于应用在盐碱重污秽地区的中低压复合绝缘产品或高力学需求的电工材料。

混杂网格增强超高性能混凝土双向板的弯曲性能

网格增强超高性能混凝土(ultra-high performance concrete,UHPC)具有轻质、高强、耐久性好等特性,已应用于薄壁结构和工程加固领域,但单一网格很难实现高效的增强增韧效应.为研究混杂网格增强UHPC双向板的抗弯性能,对3个钢丝网格与玻璃纤维网格混杂增强UHPC板、3个钢丝网格与玄武岩纤维网格混杂增强UHPC板、6个单一网格增强UHPC板和1个无网格UHPC对照板进行弯曲试验,研究网格种类、总层数及铺层方式对其破坏形态、承载能力和弯曲韧性的影响.结果表明:与单一钢丝网格板和单一玻璃纤维网格板相比,钢-玻璃纤维网格混杂板开裂后表现更显著的硬化现象,在连续网格与混杂短纤维协同效应下,板呈现多裂缝破坏模式,延性较理想.铺设2层网格时,钢-玻璃纤维网格混杂板的承载能力较单一钢丝网格板提升23.7%,且其在20 mm挠度处的残余承载力较单一玻璃纤维网格板提升28.2%;钢-玄武岩纤维网格混杂板峰前阶段的能量吸收值和20 mm挠度处的残余承载力均优于单一玄武岩纤维网格板.网格总层数为3层时,与单一玄武岩纤维网格板相比,2层钢丝网格与1层玄武岩纤维网格混杂增强板在峰前挠度为2 mm时的能量吸收值提高了21.6%,20 mm挠度处的残余承载力提高了42.6%.钢-玻璃纤维网格混杂板的网格强度利用率最理想,其承载能力、能量吸收值及弯曲韧性指标均高于钢-玄武岩纤维网格混杂板.最后,考虑网格强度有效利用率建立了混杂网格增强UHPC双向板抗弯承载力理论公式,适用性良好.

静电纺丝技术制备ETPE基多元含能复合纤维

为了探索ETPE基多元含能复合纤维的静电纺丝制备工艺,以聚叠氮缩水甘油醚基热塑性弹性体(GAP-ETPE)为聚合物黏合剂,CL-20、纳米铝粉(n-Al)作为高能组分,采用静电纺丝技术制备了GAP-ETPE基超细含能复合纤维,并对溶剂、前驱液质量分数、固相组分配比等关键工艺参数进行了优化;采用扫描电子显微镜(SEM)和透射电子显微镜(TEM)对产物形貌进行了表征,采用DSC法分析了复合纤维的热分解性能;测试了复合纤维的机械感度。结果表明,GAP-ETPE基含能复合纤维静电纺丝制备最佳溶剂为丙酮,产物成丝均匀、表面光滑;在GAP-ETPE/CL-20质量比为3∶7、前驱液质量分数为50%时,二元超细含能复合纤维(CL_(x)-ETPE_(y)-Z)的成丝效果最优,平均直径约为2480nm;在铝粉质量分数为10%、前驱液质量分数为50%时,三元超细含能复合纤维(CL-Al_(m)-ETPE-Z)的成丝效果最优,平均直径约为930nm;相比于CL-20,CL_(7)-ETPE_(3)-50含能复合纤维热分解峰值温度提前了29℃,加入n-Al之后热分解峰值温度提前了32℃,且优于物理共混物(PM);与CL-20的感度(P=100%、H_(50)=17cm)相比,GAP-ETPE/CL-20和GAP-ETPE/CL-20/Al含能复合纤维的摩擦感度(32%和48%)和撞击感度(29cm和43cm)均大幅降低,且低于同配方的物理共混物。

玄武岩纤维沙漠砂混凝土本构关系及损伤特性研究

为了有效提高沙漠砂资源化利用,研究了玄武岩纤维掺量(0、0.3%、0.4%、0.5%)对沙漠砂混凝土本构关系和损伤特性的影响。结合本构模型拟合了玄武岩纤维沙漠砂混凝土的应力-应变曲线,利用声发射事件数分析了玄武岩纤维沙漠砂混凝土损伤破坏过程,并借助速率过程理论对玄武岩纤维沙漠砂混凝土的损伤程度进行了评估。研究表明:掺入适量的玄武岩纤维(0.4%)可以减小沙漠砂混凝土构件的损坏;Carrerira J模型与试验数据具有较高的吻合度;同时还发现构件在到达峰值应力附近时,声发射事件数会急剧增加;基于速率过程理论以损伤变量D与相对荷载V之间的关系建立的损伤演化曲线,可用来评估玄武岩纤维沙漠砂混凝土的损伤破坏程度。

玻璃纤维滤材的疏水改性及过滤性能

闭式循环过程会产生大量放射性气溶胶,其高湿、高酸、高放射性的特点导致基于玻璃纤维滤材的高效过滤器失效快、更换频率高。为解决上述问题,提出对传统的玻璃纤维滤材进行疏水性改性,以提高玻璃纤维滤材对苛刻工况的耐受性。利用低表面能改性剂(聚二甲基硅氧烷)对滤材进行化学性疏水性改性,通过引用SiO_(2)纳米颗粒物进行微结构构造,进一步改善疏水效果。借助SEM、FTIR、接触角测量仪等手段对改性效果进行了分析,并进一步研究了改性滤材的过滤性能。研究结果表明:改性方案能够有效改善玻璃纤维滤材的疏水性,并提高其耐湿性;单纯化学改性滤材的静态接触角可达146°,引入SiO_(2)纳米颗粒物后改性滤材的接触角超过150°;当改性剂中聚二甲基硅氧烷质量分数为2.0%、SiO_(2)纳米颗粒物质量分数为0.5%时,所得GF-PS-0.5滤材展现出最优的耐酸性,主要源于化学性疏水和结构性疏水的有效协同;GF-PS-0.5在经受足量的γ照射后,疏水性保持稳定,表明其良好的耐辐照性;改性滤材仍然保持了优异的过滤性能,其过滤效率超过99.99%。改性过程在提高滤材耐受性的同时,没有影响其过滤性能,展现出良好的应用前景。

不同纤维对土体力学特性的影响及机理分析

为了探究不同纤维对土体加固效果的影响,将玄武岩纤维和玻璃纤维分别加入同一种土中,通过无侧限抗压强度试验,对比分析2种纤维加筋土的应力-应变曲线、强度随纤维掺量和纤维长度变化的关系;通过双根纤维锚固试验,分析纤维增强土体强度的作用机理。试验结果表明:纤维加筋土的抗压强度明显大于素土的抗压强度;随纤维长度的增加,玄武岩纤维和玻璃纤维加筋土的强度均呈现先增大后减小的趋势,纤维的最优长度均为9 mm;随着纤维掺量的增加,2种纤维加筋土强度呈现波浪式变化,存在2个峰值,纤维的最优掺量均为0.5%。通过纤维锚固试验,发现双根纤维的拉拔力随纤维间距的变化而变化,当间距较小时,纤维之间存在耦合影响,拉拔力存在峰值和谷值,随着纤维间距的增大,当达到临界锚固间距后,纤维之间互不影响。

聚氯乙烯纤维熔融纺丝及其结构与性能

为了通过熔融纺丝方法制备出性能优良的聚氯乙烯(PVC)纤维,在聚氯乙烯粉体共混改性造粒的基础上,调整熔融纺丝的工艺参数,研究纺丝温度和牵伸倍数等工艺条件对纤维结构与性能的影响,并对纤维的断裂强度、断裂伸长率、取向度、表面形貌、截面形貌以及耐酸、碱腐蚀性能、阻燃性能进行测试分析。结果表明:当喷丝板距离水浴1 cm距离、螺杆温度为160℃、喷丝板温度为190℃、热水浴温度为60℃、计量泵压力为2 MPa、牵伸倍数为4倍时,制得的PVC纤维性能较好,其断裂强度、断裂伸长率、线密度分别为1.16 cN/dtex、32.1%、12 tex,并且具有优异的耐酸、碱腐蚀性能和阻燃性能。研究结果为制备高性能的PVC纤维提供了一种新的方法。

FDM成型工艺对PEEK/CGF复合材料翘曲变形的影响

为降低连续玻璃纤维增强聚醚醚酮复合材料增材制造样件的翘曲变形,优化增材制造基础工艺参数,通过单因素试验、Plackett-Burman Design试验与Box-Behnken Design试验,研究了打印过程中的热效应,即保温舱温度、层厚、成型平台温度、打印速度等工艺参数对连续玻璃纤维增强聚醚醚酮复合材料样件翘曲变形的影响规律,得出如下结论:研究发现打印工艺对翘曲度的影响程度是不同的,影响程度依次为B(层厚)>C(成型平台温度)>A(保温舱温度)。研究发现打印工艺参数之间是会对翘曲变形产生交互作用的,并且影响程度也较为显著(PB析因试验中大于t值),即B>C>A>AB>BC>D(打印速度)>BD。研究发现喷头温度440℃,成型平台温度100℃,保温舱温度90℃,层厚0.3 mm,道间距为0.5 mm,打印速度2 mm/s时,翘曲度可达到0.23%。

高性能聚苯硫醚长丝的制备工艺

采用熔融纺丝方法通过纺丝组件的设计制备了高性能聚苯硫醚(PPS)长丝,确定了原料干燥、熔融、喷丝及缓冷区温度和吹风等条件的工艺参数,探讨了纺丝温度、纺丝速度、牵伸温度、定型温度、牵伸倍数等纺丝工艺参数对PPS纤维可纺性和力学性能的影响,确定了最佳纺丝加工工艺参数。结果表明,喷丝时初始压力控制在12 MPa以上,PPS螺杆挤出机各区温度分别为310,320,320,325,330℃,纺丝温度为300~315℃,缓冷区温度为295~310℃,纺丝速度为2 650 m/min,总牵伸倍数为4.9倍,第一热辊、第二热辊和第三热辊温度分别为95,110℃和140℃,制得规格为299 dtex/48 f PPS纤维具有良好的可纺性和优异的力学性能,拉伸断裂强度和断裂伸长率分别可达4.04 cN/dtex和16.4%。

溶液喷射纺丝参数对聚丙烯腈直径分布的影响

利用溶液喷射纺丝技术,成功制备聚丙烯腈纤维膜。采用扫描电镜观察纤维膜的形貌,探究不同纺丝工艺参数对纤维直径分布的影响。结果表明:纤维直径与聚合物质量分数、聚合物溶液挤出速度、喷丝孔内径呈正比,并且随上述工艺参数的增加,纤维直径分布较为离散;纤维直径与喷射气流的压强、接收距离呈反比,并且随上述工艺参数增加,纤维直径分布逐渐集中。经分析,获得最优工艺参数:聚合物质量分数为12%,喷射气流的压强为0.15 MPa,接收距离为70 cm,溶液挤出速度为0.3 mL/min,喷丝孔内径为0.32 mm。

喷气涡流纺莱赛尔/涤纶包芯纱的开发

为丰富喷气涡流纺纱线产品种类,文章以莱赛尔为外包纤维、涤纶DTY网络丝为芯纱,探讨了喷气涡流纺包芯纱的生产及纺纱工艺设计的重点与难点,成功开发出18.5 tex喷气涡流纺莱赛尔/涤纶包芯纱。研究表明,针对莱赛尔短纤维的特性,梳棉工序应增强梳理并提高转移效率,并条工序应提升纤维伸直平行度;喷气涡流纺工序应科学选择喂入比,正确调整芯丝喂入张力等工艺参数,合理控制喷嘴压力,加强温湿度管理。相关生产实践为开发高附加值喷气涡流纺纱线产品提供了参考。

基于负离子纤维的喷毛带子纱产品开发

以涤纶负离子中长纤为原料,经过和毛、梳理、并条、粗纱工序后制成粗纱条,在花色喷毛机上喂入到由涤纶长丝编织的带子纱中,通过改变花色喷毛机的工艺参数制成三种不同细度的负离子喷毛带子纱,织成样片后进行负离子发生量的测试和评价。结果表明,三种规格的喷毛带子纱负离子发生量皆大于1 000个/cm^(3),负离子发生量较高,能达到维持人体基本健康需求、增强免疫力的效果。纺纱试验表明,当粗纱喂入罗拉的速度控制在20 r/min~25 r/min,纱线细度控制在3 NM~3.3 NM时,所纺纱线的负离子发生量维持在最高水平。产品利用喷毛带子纱蓬松的纱线结构,使负离子纤维能更好地释放出负离子,发挥保健功效。

基于FDM的PEEK/CGF复合材料综合力学性能优化

为提升连续玻璃纤维增强聚醚醚酮(PEEK/CGF)复合材料熔融沉积成型(FDM)制品的力学性能,通过单因素试验,Plackett-Burman Design试验与Box-Behnken Design试验,研究了保温舱温度、常用打印路径(5种)、层厚、道间距等工艺参数对PEEK/CGF复合材料样件综合力学性能的影响规律,寻求最优工艺参数组合并进行试验验证。结果表明,各工艺参数对力学性能影响程度大小排序为打印路径>道间距>保温舱温度>层厚;各工艺参数之间存在相互作用,适当的工艺参数组合可以使力学性能得到大幅提升,其中相较于拉伸强度,弯曲强度受工艺参数间的相互作用更为明显;当保温舱温度为82℃、层厚为1.0 mm、打印路径为0°/0°/0°/0°、道间距为0.7 mm时,拉伸强度可得最大值为383.75 MPa,当保温舱温度为73℃、层厚为0.75 mm、打印路径为0°/0°/0°/0°、道间距为1.0 mm时,弯曲强度可得最大值510.13 MPa。