Predicting Bursting Strength Behavior of Weft Knitted Fabrics Using Various Percentages of Cotton, Polyester, and Spandex Fibers

The bursting strength is an essential quality parameter of knit fabric. The fabric structure, weight, types of fibers, and fiber blend proportion influence the bursting strength parameter. The tenacity of polyester fiber is better than cotton and spandex. The study focused on predicting knit fabric bursting strength test value using different fibers (cotton, polyester, and spandex) with varying percentages of the blend ratio. This study used fifteen categories of blended fabrics. The Pearson Correlation and the hypothetical ANOVA regression analysis were conducted to do the statistical significance test. The experimental result reveals that the bursting strength test result increased with the increased percentage of polyester and suggested a suitable regression equation. The dominance of the polyester fiber was observed throughout the experiment, i.e., the higher the polyester blend proportion, the higher the bursting strength value. The inclusion of polyester in blends can reduce the cost of fabric. The developed prediction model or equation can help the fabric manufacturer make appropriate decisions regarding getting the expected bursting strength. The researcher hopes that the findings from this study will motivate new researchers, advanced researchers, and the textile manufacturing industry.

Studying the Effect of Polyester Fiber Blend Ratio and Pilling Cycle on Blended Knit Fabrics

Pilling is a severe concern for blended fabrics. The aesthetic look and smoothness are the buyers’ prime requirements. The main focus of the study was to see the pilling behavior from various percentages of polyester fiber blend ratio as well as the different pilling cycles on blended fabrics. The cotton, polyester, and elastane prepared the study fabrics. These fabrics are (90% Cotton/5% Polyester/5% Elastane, 90% Cotton/6% Polyester/4% Elastane, 90% Cotton/7% Polyester/3% Elastane, 90% Cotton/8% Polyester/2% Elastane, and 90% Cotton/9% Polyester/1% Elastane, 85% Cotton/10% Polyester/5% Elastane, 85% Cotton/11% Polyester/4% Elastane, 85% Cotton/12% Polyester/3% Elastane, 85% Cotton/13% Polyester/2% Elastane, and 85% Cotton/ 14% Polyester/1% Elastane, 80% Cotton/15% Polyester/5% Elastane, 80% Cotton/16% Polyester/4% Elastane, 80% Cotton/17% Polyester/3% Elastane, 80% Cotton/18% Polyester/2% Elastane, and 80% Cotton/19% Polyester/1% Elastane). The selected polyester blend ratios were 5%, 6%, 7%, 8%, 9%, 10%, 11%, 12%, 13%, 14%, 15%, 16%, 17%, 18% and 19% respectively. The study used the Martindale pilling tester with 2000, 5000, and 7000 cycles, respectively. The evaluation followed the ISO 12945-2:2000. The study findings are that the polyester fiber blend ratio did not influence the pilling grade on blended fabrics for pilling cycles 2000, and the pilling grade remained constant at 4 - 5. The pilling grade started to deteriorate in pilling cycle 5000 for the fabrics 85%C/10%P/5%E, 85%C/11%P/4%E, 85%C/12%P/3%E, 85%C/ 13%P/2%E, 85%C/14%P/1%E showed the pilling grade 4, and the fabrics made from 80%C/15%P/5%E, 80%C/16%P/4%E, 80%C/17%P/3%E, 80%C/ 18%P/2%E, 80%C/19%P/1%E showed the pilling grade 4, 3, 3, 3, and 3 respectively. For the pilling cycles 7000, the pilling grade further deteriorated for the fabrics 80%C/15%P/5%E, 80%C/16%P/4%E, 80%C/17%P/3%E, 80%C/ 18%P/2%E, 80%C/19%P/1%E showed the pilling grade 3, 3, 2, 2, and 2 respectively. The study finds the dominance of polyester fiber throughout the experiment. The author hopes this study’s outcome will help new researchers, advanced researchers, and the textile industry’s sustainable development research and development team.

Finishing Effect on Warmth Property of Cotton/Kapok Blended Knitted Fabric

Nowadays,more and more natural or functional fibers are being investigated due to their utilization in thermal underwear.Kapok fiber is one of the natural cellulosic fibers whose source is the kapok plant. It has hollow body and sealed tail,which exhibits desirable features required for functional textiles of this nature. In this study,cotton / kapok( 80 /20 by mass) blended yarn with two types of yarn size 18. 5 and 14. 8 tex,respectively are knitted into plain stitches. The fabrics are undergone with an optimal preparation plan according to orthogonal design. Then,after dyeing and softening,fabric properties including thermal and water-vapour resistances, wicking property, pilling behaviour, and surface morphology,are tested and scrutinized for their candidacy for thermal underwear. The results showed that cotton / kapok blended fabrics have good thermal resistance which is significantly higher than those of cotton / modal blended fabrics,and the same water vapour resistance compared with cotton / modal blended fabrics which are normally used as underwear. Cotton / modal blended knitted fabrics has better pilling grade than cotton / kapok blended fabrics. Meanwhile, the cotton / kapok blends fabrics have good wicking property. Collectively,it was concluded that cotton / kapok blended fabric was appropriate for thermal underwear. However,the main limitation of these fabrics is their pilling properties.

壳聚糖基膨胀阻燃涤纶/棉混纺织物的制备及其性能

为得到阻燃且满足实际应用需求的涤纶/棉混纺织物(T/C),选用亚磷酸化壳聚糖(PCS)和γ-哌嗪基丙基甲基二甲氧基硅烷(GP-108)制备阻燃整理剂(PCS/GP),通过一步浸渍法对涤纶/棉混纺织物进行整理,并研究其微观表面形貌、热稳定性能、阻燃性能、拉伸性能以及白度等。结果表明:PCS/GP成功在涤纶/棉混纺织物表面沉积成膜,包裹住涤纶/棉纤维;T/C-PCS/GP呈现典型的涤纶/棉混纺织物二步热降解过程,在700℃时保留有28.5%的残炭量,说明PCS/GP提高了阻燃涤纶/棉混纺织物在高温区的热稳定性能;T/C-PCS/GP的LOI值提升至26.5%,实现了垂直燃烧测试中的离火自熄,残炭扫描电镜照片表明,PCS/GP的沉积改善了涤纶/棉混纺织物燃烧时存在的“支架”效应;T/C-PCS/GP的热释放速率峰值和火灾蔓延指数较T/C分别降低了20%和40%,表明其火灾危险性大幅度降低;锥形量热测试后的残炭电镜照片表明,T/C-PCS/GP能够保留完整的织物编织结构,残炭表面存在明显的膨胀炭层,与垂直燃烧测试结果相符;热重红外测试结果表明,T/C-PCS/GP分解提前,主要影响棉组分热降解并促进其成炭,而高温区的红外谱图表明,在致密炭层的保护下,T/C-PCS/GP的热降解得到抑制。T/C-PCS/GP与T/C-PCS相比,断裂强力提升17%,其断裂强力与T/C的断裂强力相差不大;同时,GP-108的使用改善了T/C-PCS的黄变问题,提升了T/C-PCS/GP的白度。然而,阻燃样品耐久性较差,需要后续改进。

磷-氮-硅协同阻燃/抗菌涤棉织物的制备与性能

为实现涤棉织物的阻燃/抗菌协同整理,以3-氨丙基三乙氧基硅烷(APTES)和9,10-二氢-9-氧杂-10-磷杂菲-10-氧化物(DOPO)为反应物,分别合成了八氨丙基八硅倍半氧烷和2-氯乙基DOPO,通过轧烘焙方法将其整理到涤棉织物上,并对其进行氯化处理。结果表明:阻燃/抗菌整理涤棉织物的阻燃等级达到B1级;整理后未氯化的织物在30 min接触时间内对金黄葡萄球菌和大肠埃希菌的对数减少值分别达到2.56 log和2.06 log,而经氯化处理后其能够在1 min的接触时间内杀灭接种的细菌,表现出迅速且优异的抗菌性能。

精梳工艺路线对涤棉混纺面料风格影响

为了探讨不同精梳加工路线对涤棉混纺面料风格的影响,将涤纶与棉纤维分别精梳后按照65/35进行混纺制成涤棉混纺精梳纱,同时将普梳涤纶与精梳后的棉纤维进行混纺制成涤棉混纺半精梳纱。将涤棉混纺精梳纱和涤棉混纺半精梳纱利用相同的织造及染整工艺分别制成涤棉混纺精梳面料和涤棉混纺半精梳面料,利用KES织物风格仪测试两种面料的拉伸、剪切、弯曲、压缩、表面等风格特征。结果表明:与涤棉混纺半精梳面料相比,涤棉混纺精梳面料的各风格特征均有改善,其中变化最显著指标:抗弯刚度减小20%,弯曲滞后距减小17%,压缩比功减小22%,摩擦因数波动减小18%。认为:涤棉混纺精梳面料比涤棉混纺半精梳面料具有更好的柔软性、光滑性、回弹性。

BCI棉/再生涤混纺针织织物染整工艺

采用活性染料/分散染料对BCI棉/再生涤混纺针织织物进行染色,比较不同染色工艺的得色效果、耐汗渍色牢度、耐皂洗色牢度、耐摩擦色牢度以及耐光色牢度等指标,筛选BCI棉/再生涤混纺针织织物的大生产工艺,从而减少实际大生产时染色带来废水对环境造成的污染,以优化染色质量与成本。实验结果表明:选择方案4#进行印染加工更加节约用水成本、时间成本、用电成本。染色织物耐干摩擦色牢度可达4~5级,耐湿摩擦色牢度可达3~4级,耐皂洗色牢度可达4~5级,耐汗渍色牢度达到4~5级,具有生产可行性。

涤棉针织物练染一浴工艺

针对涤棉针织物染整工艺流程长、耗水耗能高、生产效率低等问题,采用RY236对涤棉针织物进行练染一浴加工,分别讨论了双氧水用量、练染浴pH、保温时间及RY236用量对纯棉针织物前处理效果以及纯涤针织物染色性能的影响。优化后的练染一浴工艺:双氧水用量为8 g/L,pH为5.5,RY236用量为1 g/L,染色温度为130℃,保温30 min。与传统工艺相比,该工艺能够降低生产成本,提高生产效率。

植酸/壳聚糖对涤纶/棉混纺织物的协同阻燃整理

针对涤纶/棉混纺织物的易燃问题,采用植酸(PA)和壳聚糖(CS)构成膨胀阻燃体系,通过浸渍烘焙法对涤纶/棉混纺织物进行阻燃整理,并对整理前后织物的化学结构、表面形貌、热稳定性、燃烧行为、力学性能及耐水洗性等进行探究。通过工艺调控与优化,获得最佳阻燃整理工艺:烘焙温度160℃,烘焙时间120 s,CS质量浓度30 g/L,PA质量浓度400 g/L。经过阻燃整理后,所得涤纶/棉混纺织物的极限氧指数值由17.8%上升到28.7%,达到难燃级别;热重结果表明,相较于原涤纶/棉混纺织物,阻燃涤纶/棉混纺织物的分解速率下降,高温热稳定性显著提高,在氮气气氛下,800℃时残炭率提高到25%以上;阻燃涤纶/棉混纺织物的最大热释放速率由原涤纶/棉混纺织物的145.86 kW/m^(2)下降到96.96 kW/m^(2),总热释放量由原涤纶/棉混纺织物的2.75 MJ/m^(2)下降到2.06 MJ/m^(2);PA和CS在织物表面构成膨胀阻燃涂层,显著提高了织物的阻燃性能。

废旧涤/棉混纺织物回收再利用研究进展

随着人们生活水平不断提升,服装更换周期缩短,废旧纺织品的处理问题日益凸显。文章针对目前废旧涤/棉混纺织物量大但回收利用率低的现状,主要介绍了此类织物回收再利用的常用方法,详细阐述了醇解法、离子液体法、水热法分离涤棉的研究进展,并对回收利用废旧涤棉纺织品的前景进行了展望。

涤纶/棉混纺织物在水热体系中的降解

为实现废弃涤纶/棉混纺织物的循环利用,以金属盐硫酸铜作为添加剂,采用绿色、经济的水热法对废弃涤纶/棉混纺织物进行降解,研究在硫酸铜-水热体系中涤纶/棉混纺织物的降解行为。结果表明:棉与涤纶在硫酸铜-水热体系中表现出不同的降解行为;在低温水热条件下,棉纤维在非晶区发生降解生成粉末状纤维素及少量葡萄糖,而涤纶在低温下则保持其纤维形貌及理化性质不变,可实现双组分涤纶与棉的分离;在高温水热条件下,涤纶发生降解生成对苯二甲酸,其得率可达91%以上,而棉纤维在高温下则降解炭化形成富含含氧基团的炭材料,实现了涤纶与棉在同一体系中的同时降解;高温环境中涤纶与棉同时降解不会影响棉纤维炭产物的晶体结构,但会对炭产物的形貌有一定影响。该水热降解工艺在低温下可实现涤纶/棉混纺织物双组分的分离,高温下可实现涤纶与棉在同一体系中共同降解的行为,具有一定的实用价值,为废弃涤纶/棉混纺织物的回收利用提供了一定参考。

涤/棉混纺针织物高效漂染一浴两步工艺

高效漂染一浴两步工艺代替常规漂染工艺处理涤/棉混纺针织物,具有良好的棉精练及涤染色效果。工艺条件为:TF-213HL 0.5%(omf),分散染料0.5%(omf),浴比1∶10,130℃处理30 min,不排液降温至85℃处理30 min,并加入TF-1291K 1.0%(omf),NaOH 0.6%(omf),H_(2)O_(2)8.0%(omf)。

涤棉混纺织物分散/活性染料一浴一步法染色应用

涤棉混纺织物采用常规工艺进行染色能够获得较好的色牢度,但是染色时间长而且污水处理成本高,不符合低碳环保的要求。采用分散/活性染料一浴一步法染色改进工艺替代常规工艺。在常温(40℃)状态下,以元明粉150 g/L,促染剂1 g/L,2℃/min升温至80℃并保温1 min,以1℃/min升温至95℃并保温1 min,以1℃/min升温至127℃并保温30 min进行分散染料与活性染料染色。实验结果表明,染色织物耐干摩擦色牢度可达4~5级,耐湿摩擦色牢度可达3~4级,耐皂洗色牢度可达4~5级,耐汗渍色牢度达到4~5级,同时能够缩短染色时间、节约用电、减少污水排放,对降低生产成本起到了积极作用,满足了实际生产需求。

二醋酯纤维与棉混纺针织物染整工艺探讨

二醋酯纤维诞生已有近百年的历史,但因棉与二醋酯纤维混纺面料在染整过程仍然存在一些技术难点,目前二醋酯纤维与棉的混纺应用相对较少。文中主要探讨二醋酯纤维与棉混纺织物在染整过程中的技术难点,主要针对二醋酯纤维遇碱皂化以及色牢度偏低的技术难点,提供详细的低温前处理方案、酸性还原清洗方案、低温皂洗方案以及高效涤棉固色等解决方案,为二醋酯纤维与棉混纺织物的研究以及工业化生产提供参考。

棉与涤纶长丝并捻工装面料的生产实践

为了解决传统棉/涤混纺工装面料容易起毛起球、耐磨性差、断裂强力低等问题,采用2根CJ 10.8 tex纱与1根涤纶长丝并纱的方式代替棉涤短纤维混纺纱,详述其清花、梳棉、精梳、并条、粗纱、细纱、倍捻、整经、浆纱等工序的控制要点,并对成品面料主要质量指标进行分析。结果表明:采用单纱和长丝并纱再进行并捻纱线,代替棉涤短纤混纺纱织造的成品面料,抗皱性和耐磨性好,面料光滑柔顺,耐摩擦色牢度和耐刷洗色牢度好,悬垂性和挺括性也大幅提高。

EHD喷墨打印硅橡胶/碳纳米管涂层织物的制备及性能研究

文章选用涤棉针织物为基材,将不同质量分数的硅橡胶(SR)/碳纳米管(CNTs)溶液通过电流体动力(EHD)喷墨打印的方式喷涂于基材上,得到SR/CNTs涂层导电织物,并探讨了CNTs质量分数对涂层织物性能的影响。随着CNTs质量分数的增加,导电织物上沉积的CNTs变多,力学性能和导电性能得到改善。其中,用质量分数为9%的CNTs溶液沉积的导电织物,在平行于线圈方向上,拉伸强度最大为14.40 Mpa,导电织物的电学性能最佳,工作范围可达111.10%,灵敏度系数最高为2.49。该导电织物具有优异的电学性能,在智能可穿戴领域具有广泛的应用前景。

涤棉针织面料的染整碳排放分析

概述了目前碳足迹现状以及温室气体排放标准,分析了涤棉针织面料染整过程中的碳排放源,以及碳排放的核算标准和计算方法,得出其碳排放为1.909 kgCO_(2)/kg。研究发现,涤棉针织面料染整加工中碳排放比例最多的为煤炭能源产生的蒸汽消耗,建议采用湿短蒸染色工艺,以减少固色用的烧碱、纯碱和皂洗用水。

聚酯与棉混纺织物碱-SA表面处理及喷墨印花

使用阳离子型表面活性剂十六烷基二甲基苄基氯化铵(HDBAC)、氢氧化钠、海藻酸钠(SA)等对聚酯与棉混纺织物进行碱-SA表面处理。通过印花颜色性能和色牢度分析处理后织物活性染料喷墨印花效果。通过纤维表面形貌、润湿性、表面Zeta电位等数据推断作用机理。结果表明,碱-SA表面处理后织物的活性染料喷墨印花K/S值提高,印花织物色牢度较好,织物的活性染料喷墨印花效果得到显著改善。

棉/生物基弹性聚酯纤维混纺针织物的服用性能

针对生物基弹性聚酯(PTT)纤维因自身特性难以单独成条纺纱的问题,设计在清花工序运用3种不同形态棉纤维辅助PTT纤维成卷成条,并采用赛络纺方式制成线密度为14.7 tex的棉/PTT纤维(60/40)混纺纱,然后织成纬平针织物比较分析其顶破性、起毛起球性、耐磨性、透气性、透湿性及悬垂性能,最后用模糊综合评判模型对织物性能进行综合评判。结果表明:棉纤维的伸直程度高,可加大与PTT纤维间的摩擦力,提高了混纺针织物的顶破性、抗起毛起球性、透气性;织物表面PTT纤维含量多,则耐磨性较佳;而透湿性与悬垂性能与棉纤维形态基本无关。基于模糊评价模型判定,选用精梳棉条辅助PTT纤维成卷的混纺针织物的综合服用性能较佳。

混纺比对棉/丝光羊毛针织物性能的影响

为了开发高品质棉毛混纺针织物,探讨羊毛纤维含量变化对棉毛混纺纱及其针织物性能的影响。采用3种混纺比和2种纺纱方式纺制了6种纱线及其针织物,并对6种针织物的耐磨、强力、热湿舒适性以及织物风格等性能进行了测试。结果表明:纤维含量对织物的风格特征影响并不显著,羊毛纤维含量的增加使织物的保暖性和抗折皱性增强,但也会在一定程度上降低织物的强力、耐磨性,使织物的透气透湿性变差,企业在实际应用中可根据织物的服用性能与客户需求选择混纺比,从而获得合适的织物品质和性能,获得良好的经济效益。