Optimization of Photo-Fenton Catalyst Preparation Based Bamboo Carbon Fiber by Response Surface Methodology

In this paper,the residue from bamboo factory has been used to design photo-Fenton catalyst,which has the advantages of low cost and magnetic recycling.The photo-Fenton catalytic performance of the biocarbon-based catalyst was excellent and its optimal preparation process was also explored by response surface methodology.First,bamboo-carbon fiber was selected as the photo-Fenton catalyst carrier.Subsequently,the surface of the car-bon fiber was modified,with which dopamine,nano-Fe_(3)O_(4) and nano-TiO_(2) were successively loaded by hydro-thermal method.After the single factor tests,four factors including dopamine concentration,ferric chloride mass,P25 titanium dioxide mass and liquid-solid ratio were selected as the characteristic values.The degradation efficiency of photo-Fenton catalyst to methylene blue(MB)solution was treated as the response value.After the analysis of the response surface optimization,it was shown that the significance sequence of the selected 4 factors in terms of the MB degradation efficiency was arranged as follows:dopamine concentration>liquid-solid ratio>P25 titanium dioxide quality>ferric chloride quality.The optimal process parameters of fiber-carbon catalyst were affirmed as follows:the 1.7 mg/mL concentration of dopamine,the 1.2 g mass of ferric chloride,the 0.2 g mass of P25 titanium dioxide and the liquid-solid ratio of 170 mL/g.The experiment-measured average MB degra-dation efficiency performed by the optimized catalyst was 99.3%,which was nearly similar to the model-predicted value of 98.9%.It showed that the prediction model and response surface model were accurate and reliable.The results from response surface optimization could provide a good reference to design bamboo-based Fenton-like catalyst with excellent catalytic performance.

A Study on the Surface Structures of Viscose-based Activated Carbon Fiber by FT-IR Spectroscopy and XPS

Using viscose fiber (VF) as starting material and common steam as activating agent, formation of oxygen structures in activated carbon fiber is investigated. In the preparation of samples, VF was first heated at temperatures between 450℃ and 900℃ in N2 artmosphere. Then, in a successive activation stage, the product carbonized at 600℃ was activated in steam at 450 - 900℃ for 30 min, and at 600℃for 5- 30 min. The other carbonization products were activated at 600 and 900℃ for 30 min respectively. The products activated at 900℃ were then activated at 450℃ for 30 min again. The starting material, carbonized products and all activation products were examined by FT-IR spectroscopy and some products were examined by X-ray photoelectron spectroscope (XPS). And the yields of the carbonized and activated products were calculated. By analysing these spectra, the amount of oxygen-containing functional groups of the activated products attained under various activation time, various activation temperature and various previous carbonization temperature was determined.

Identification of Bamboo Viscose Fibers and Conventional Viscose Fibers

Bamboo viscose fibers and conventional viscose fibers were measured by optical microscopy, scanning electron microscopy (SEM), Fourier transform infrared spectrometer (FTIR), and thermogravimetric analyzer/FTIR spectrometer (TG-FTIR) respectively. At last, the method based on the testing of the Fourier transform near infrared (NIR) spectra was proposed to identify these two kinds of fibers. The discrimination models between bamboo viscose fibers with conventional viscose fibers were built by means of Ward's algorithm and Hierarchical cluster analysis(HCA) after the first derivative and vector normalization pretreatment, and were verified finally. The results indicate that these two kinds of fibers are similar in their morphology both of cross-section and longitudinal direction. What's more, the FTIR spectra, the thermostability, and decomposition products of TG-FTIR experiment are similar, and the testing results contribute little to the effective identification of the two fibers. However, the accuracy of the NIR spectra model is high, and the two kinds of fibers can be classified into two separated groups to achieve the identification simply and exactly.

Comparison between the Direct Dyeing Kinetics of Bamboo and Conventional Viscose Fibers

Two direct dyes were applied to conventional viscose(CV)and bamboo viscose(BV)fibers,which were prepared from bamboo cellulose pulps,and the dyeing kinetics of two fibers were compared.Three kinetic equations,namely Chrastil,Cegarra-Puente,and Vickerstaff,were used to fit the experimental dyeing rate points,showing that the best result was obtained by the Chrastil equation.BV fibers displayed slightly higher dyeing rates and dye adsorption values at initial stages,but a bit lower dye adsorption values at equilibrium than CV fibers.Furthermore,the dyeing of BV fibers exhibited lower activation energies and higher dyeing rate constants than that of CV fibers,and therefore showed slightly lower dependence on temperature.

树脂黏度对碳纤维与环氧树脂浸润性及界面结合性能的影响

碳纤维与环氧树脂基体形成良好的界面结合是发挥复合材料基本性能的保障,考察3种国产T700级碳纤维,研究树脂黏度对碳纤维浸润性以及界面结合性能的影响。结果表明:由室温升到60℃,树脂体系黏度从1401.9mPa·s降低到102.77mPa·s,碳纤维与树脂的接触角减小,浸润能力增强,从而提高复合材料的界面结合强度,在60℃下制备的复合材料层间剪切强度提高了17.44%。同时纤维表面的沟槽结构能够加强物理机械互锁作用,加强复合材料的界面结合强度。

竹纤维粒径与比例对石竹塑复合材料的性能影响

【目的】阐明不同竹纤维粒径和原料配比对竹纤维/聚丙烯/碳酸钙复合材料物理力学性能的影响机理,为石竹塑复合材料的工业化生产与应用提供依据。【方法】以碳酸钙、竹纤维和聚丙烯为原料,在控制竹纤维粒径(40目、80目和120目)与原料配比的基础上,制备竹纤维/聚丙烯/碳酸钙复合材料,考察其物理力学性能,并采用扫描电子显微镜、热重分析仪和熔融指数仪对复合材料的微观结构、热稳定性和流动性进行表征。最后,综合考虑生产成本与相关性能要求,为竹纤维/聚丙烯/碳酸钙复合材料的生产与应用提出建议。【结果】随着碳酸钙添加量的增加,复合材料的拉伸强度、弯曲强度和弹性模量均逐渐下降,而密度则呈上升趋势。竹纤维粒径对复合材料物理力学性能的影响较为显著。当竹纤维粒径为80目,碳酸钙和竹纤维添加量分别为5%和45%时,复合材料的拉伸强度、弯曲强度和弹性模量最优,分别为36.09 MPa、62.6 MPa和4.30 GPa。碳酸钙添加量对复合材料冲击强度的影响不大。此外,随着碳酸钙添加量的增加,复合材料的热稳定性与熔体流动性均有所改善。当碳酸钙添加质量占比为20%时,复合材料的熔体流动速率为16.50 g/10 min,比未添加组提高了8.98%,加工性能得到改善。【结论】选用80目竹纤维的复合材料具有较优的物理力学性能,在添加碳酸钙后,复合材料的原料成本可降低1.63%~6.54%,且其相关指标仍远高于行业标准要求。

仿生竹节纤维基加湿材料的叠层设计及其导湿快干性能

为开发兼具快速导液能力和一定抗拉强度的新型纤维基加湿芯,利用熔喷原位牵伸工艺制备的高定向排列聚乳酸(PLA)微纳米纤维材料与大孔隙粘胶纤维材料进行叠层复合,得到筒状纤维集合体,并对其形貌特征、吸湿速率、干燥速率以及力学性能等进行表征与测试。结果表明:筒状纤维集合体表现出类竹节形貌的层状定向微孔结构,密度为1.1~1.8 g/cm^(3);受益于纤维平均直径和密度的有效调控,吸湿速率和干燥速率分别增加到112.4 mg/s和1.03 mL/h,同时拉伸断裂强力保持在255.2 N以上。仿生竹节纤维基加湿材料样品在实际使用过程中的加湿量为39 mL/h,既可作为高性能纤维基加湿芯用于室内微环境湿度调节,又可为高导液纤维材料的功能性结构设计和绿色制备提供参考。

纯纺再生纤维素纤维纱线特点和浆纱工艺

为提升再生纤维素纤维纱线的浆纱质量,分析对比粘胶、莱赛尔、莫代尔和竹浆纤维等4种再生纤维素纤维的化学组成成分和微观结构的异同点、物理指标的差异以及对应集聚纺纱线指标和织物规格;通过对比试验,确定浆液含固量、粘度、上浆率、伸长率、温度和回潮率等主要浆纱工艺参数,分析其技术难点及浆纱质量指标。指出:不同纤维素纤维微观结构不同,物理性能指标差异较大,在高压高温湿热的浆纱条件下,要根据纤维的成分、纱线号数采取适宜的工艺参数,以保证浆纱质量稳定、织造顺利进行和良好的布面质量。

艾草改性竹浆纤维性能测试与分析

为探讨艾草改性竹浆纤维的可纺性,对艾草改性竹浆纤维的形貌、组成、结构、强伸性能、质量比电阻、回潮率、摩擦系数等进行测试,并与竹浆纤维、黏胶纤维进行对比。结果表明:3种纤维纵向都有沟槽,横截面呈锯齿形并带有微孔;艾草改性竹浆纤维和黏胶纤维的元素含量相同;艾草改性竹浆纤维的结晶度最小;艾草改性竹浆纤维的耐热性较黏胶纤维好,较竹浆纤维稍差;艾草改性竹浆纤维的断裂强度及断裂伸长率均最小;艾草改性竹浆纤维的初始模量小,易变形;艾草改性竹浆纤维的回潮率较大,吸湿性能优于黏胶纤维和竹浆纤维;艾草改性竹浆纤维的摩擦系数略大于黏胶纤维,竹浆纤维最小;艾草改性竹浆纤维的质量比电阻小于竹浆纤维和黏胶纤维,具有良好的抗静电性能。

基于Friele模型的转杯纺黏胶混色针织物测配色系统

以红、黄、蓝3色原液着色黏胶短纤维为原料,采用多通道转杯纺技术,以质量比为10%的梯度纺制66种混色纱线,制备针织物样品,利用分光光度计测试其颜色特征。对Friele模型的关键参数σ在[0,1]内进行赋值以预测样品色彩,计算得出σ=0.134时双组分混色样品平均色差最小;取该值构建基于Friele模型的多通道转杯纺黏胶织物配色系统,利用全光谱配色法和所建模型预测3组分混色样品的配方比例,所得预测比例与实际比例间的平均比例误差为10.21%,平均色差为0.4561。研究结果验证了所建Friele模型的准确性,并为完善多通道转杯纺黏胶混色纺织品智能配色系统提供了依据。

煤矿乏风瓦斯提浓研究

针对煤矿乏风瓦斯排放量大、所含甲烷对环境影响严重,且甲烷含量极低、无法直接利用的问题,开展了乏风瓦斯提浓研究。简述了煤矿乏风瓦斯排放特点及不同提浓方法的优缺点,确定了乏风瓦斯提浓采用变温吸附技术;以黏胶基活性炭纤维作为吸附剂开展了吸附等压线实验,实验得出:常压下、温度为20℃时吸附剂的甲烷吸附量为0.570 mol/kg,并确定了吸附剂的脱附温度为120℃;在此基础上设计了2500 m^(3)/h乏风瓦斯变温吸附提浓装置,运行结果表明,乏风瓦斯中甲烷体积分数可由0.29%提升至0.68%。

高性能纤维及其制品颜色构建的研究进展

高性能纤维及其制品是我国纺织行业重点发展的关键材料,其关系到国民经济发展和国家战略安全。为促进高性能纤维及其制品的发展,掌握其染色方法前沿和发展趋势,突破行业技术瓶颈,综述了国内外高性能纤维及其制品颜色构建的研究进展。重点概述了以芳纶、碳纤维、聚酰亚胺纤维和超高分子量聚乙烯纤维为代表的高性能纤维在颜色构建方面的技术创新,从载体染色、非水介质溶剂染色和原液着色等化学染色法以及物理结构生色法等方面总结了4种高性能纤维颜色构建的基本原理和发展趋势,讨论了高性能纤维色彩构建中遇到的主要挑战,并对该领域的未来研究方向进行了展望。指出,高性能纤维及其制品的颜色构建仍需进一步完善理论研究,以期为推动其高质量发展提供理论和应用参考。

光子晶体结构生色碳纤维/涤纶混纺纱线的制备及其性能

针对碳纤维难着色的问题,提出利用结构生色实现碳纤维/涤纶混纺纱线的着色。以聚(苯乙烯-甲基丙烯酸)胶体微球为结构基元,利用浸渍提拉法在碳纤维/涤纶混纺纱线上构筑光子晶体生色结构。分析组装液质量分数和自组装温度对结构色的影响,探究胶体微球在纱线表面组装成光子晶体的过程,利用聚二甲基硅氧烷(PDMS)封装技术提升结构生色纱线的色彩耐久性。结果表明:当组装液质量分数为70%、自组装温度为40℃时,可以在纱线表面构筑得到结构色明亮的光子晶体;胶体微球在纱线表面的组装过程归纳为预备阶段、堆砌聚集和完备阶段;经PDMS封装后的结构生色纱线经历水洗摩擦后依旧保持原有的色彩鲜艳度。该研究可为实现彩色碳纤维制品的现代化生产和应用提供新的策略。

黏胶纤维织物低尿素印花技术探讨

从黏胶纤维前处理工艺、活性染料开发、生产过程控制和印花糊料选择4个方面研究黏胶纤维织物的低尿素印花技术。结果表明:黏胶纤维采用低温轧碱前处理新工艺,可使黏胶纤维印花织物的相对色深明显增加,特别是经活性艳蓝和活性翠蓝印花的黏胶纤维织物,其相对色深增加了20%以上;开发低尿素依存性活性染料,可降低50%以上的尿素使用量,部分染料品种可不使用尿素;通过控制织物进入蒸化工序前的含湿率在20%~30%,可有效提高印花织物的相对色深;使用合成复配糊料能够起到尿素的部分作用,可使印花织物的相对色深提高10%以上。

竹浆纤维水热炭微球结构可控制备研究

为了实现结构可控的水热炭微球制备,以竹浆纤维为原料系统研究了水热反应条件(反应温度、反应时间和原料用量)对产物微观形貌和理化结构的影响,采用SEM、XRD、FT-IR和XPS等表征手段对材料特性进行深入探究。研究结果表明:在反应温度220℃、反应时间6 h、竹浆纤维用量6 g时,获得炭微球颗粒分散、尺寸分布较为均匀,样品固相碳得率最高达到24.3%,表明制备水热炭具有良好的固碳作用。XRD结果表明水热炭是一种无定形晶体,官能团分析显示水热炭表面富含羟基、羰基、酯基和醚键等一系列含氧官能团;产物比表面积主要介于23.2~83.7 m^(2)/g,孔隙以介孔为主,孔径主要分布于3~8 nm,最大孔容为0.35 cm^(3)/g。

Animal Experiment of Viscose Carbon Fiber Based C/C Composites Applied in Bone Fracture Intramedullary Fixation

The animal experiment of viscose carbon fiber based C/C composites applied in bone defection intramedullary fixation was carried out in New Zealand white rabbits.The histological observation on the 100th day after surgical operation indicated that the experimental animals recovered well and the bone defect area was reconstructed by new bone trabecula.Immunohistochemical observation of leukocyte common antigen and macrophage suggested that intramedullary fixation materials did not induct any chronic toxicity reactions such as inflammatory reactions,macrophage reactions and formation of granulation tissue.The tissue compatibility of this material was excellent.Meanwhile,the impurity element species and the biological toxic element content of viscose fiber based C/C composites were determined by atomic fluorescence analyzer and inductively coupled plasma atomic emission spectrometry.The results reveal that there are few biological toxic elements in the viscose fiber based C/C composites and it can satisfy the constituent demands of surgical implants.

基于视觉感知的转杯混色纱颜色评价研究

研究基于视觉感知的主客观转杯混色纱颜色评价方法。简要介绍了颜色主观评价法和基于3种色差公式的客观评价法。选用红、黄、蓝3种原液着色粘胶散纤维作为试验原料,纺制53个混配比例的粘胶58.3 tex转杯纱颜色样品。对色纺纱样品对的色差进行人眼视觉评价试验和色差公式计算。通过PF/3和STRESS评价指标研究目测感知量与色差计算值两组数据的相关程度,采取误判率及反射率偏差方法对观察者数据准确性加以佐证,探究针对于色纺纱与人眼一致性程度最为相符的色差公式。研究结果显示:CMC(2∶1)、CIELAB、CIEDE2000色差公式的PF/3和STRESS值分别为19.02、22.33、41.24和24.72、28.78、40.47。在该研究范围内,CMC(2∶1)色差公式的预测性能最优。

竹浆纤维和黏胶纤维的定性与定量方法

竹浆纤维和黏胶纤维由于化学成分类似,给二者的鉴别与定量分析带来难题。只采用单个常规定性方法难以区分,结合TG法、SEM法结果表明,竹浆纤维的横截面边缘更平滑,且有部分边缘锯齿倒卷从而形成腔体与缝隙,高温下分解更快,更快达到失重平衡,TG法和SEM法结合可定性鉴别;IR法得到黏胶纤维羟基的吸收峰明显高于竹浆纤维,竹浆纤维初始溶解速度更快,IR法和溶解法结合可定性鉴别。以60%硫酸作为溶解介质,通过UV-Vis和数学模型进行定量,结果表明,α系数值可控制在-1.387 8~-1.264 6,试验结果与真实混合比例误差为-0.41%~2.54%,满足误差允许范围,具有一定准确度。

竹束精细疏解与炭化处理对重组竹性能的影响

以去青留黄的竹片为原料,利用纤维原位可控分离技术,对竹片进行精细化疏解处理,再经浸胶、干燥后,采用热压法制备重组竹,并与普通的本色重组竹、低温炭化重组竹、高温炭化重组竹以及竹基纤维复合材料进行对比。结果表明:高温热处理是提高重组竹的耐水性能和尺寸稳定性的有效方法之一,其缺点是力学性能损失严重,静曲强度损失率达到45%;与高温炭化处理相比,精细疏解加工工艺简单,加工的重组竹力学性能基本不损失,且能更有效地改善重组竹的耐水性能和尺寸稳定性;与普通本色重组竹相比,采用精细化疏解竹束制备的重组竹,其吸水率降低75%,吸水厚度膨胀率降低67%,耐水性能和尺寸稳定性接近竹基纤维复合材料。

咖啡炭纤维混纺织物的性能

为开发一种新型功能面料,先测试了咖啡炭纤维的性能,然后将其与其他纤维混纺试制了2个系列8种织物并测试分析其服用性能。结果表明:咖啡炭纤维的横截面中腔结构明显,其纵向表面有很多纳米级咖啡炭颗粒附着;与普通涤纶纤维相比,其初始模量、断裂强度、断裂伸长率均较低,回潮率有所增大;咖啡炭纤维与棉纤维、粘胶纤维、莫代尔纤维等混纺,其织物性能有较大差异,其中含量为35%的咖啡炭纤维与棉纤维混纺时,其织物保暖性能最好,与粘胶纤维混纺的织物有较佳的透气性能;与粘胶、莫代尔纤维混纺的织物有较佳的热湿舒适性能、抗起毛起球性及保型性;与莫代尔、棉纤维混纺的织物折皱回复性较优。