直接染料对雄蚕丝的染色性能

探讨了中性盐、温度、染料用量对雄蚕丝直接染料染色性能的影响,比较了雄蚕丝、普通蚕丝和棉的染色性能。实验结果表明：中性盐对染色起到促染作用;随着温度的升高,上染百分率增加;上染百分率随着染料浓度的增加而降低。雄蚕丝的上染速度和上染率明显高于普通蚕丝和棉纤维。     

染色对PTT纤维聚集态结构的影响

研究了染色温度和时间对PTT纤维上染率和聚集态结构的影响。结果表明,随染色温度升高,PTT纤维的上染率提高,最佳染色温度为110℃;在110℃时,染料分子容易进入纤维的非晶区,染色开始时纤维的上染率明显升高,染色时间对纤维上染率的影响不大;在90℃时,染色前期PTT纤维的上染率较低,随着染色时间的延长,纤维的结晶度和晶区取向降低,上染率明显升高;在130℃时,纤维的冷结晶过程容易发生,大分子链排列紧密,纤维的上染率降低。     

直接染料对甲壳胺纤维的染色性能

探讨了中性盐、温度、染料用量对甲壳胺纤维直接染料染色性能的影响，比较了脱脂棉和甲壳胺纤维的染色性能。实验结果表明：中性盐对染料的影响与染料的磺酸基的数目有关，对4～6个磺酸基，中性盐起促染作用．对双磺酸基，起缓染作用：而在70℃时染色的上染速度明显快于40℃，染料浓度在2％时几乎尽染，当上升到8％时上染率仍在70％以上；甲壳胺纤维的上染速度和上染率明显高于棉，其可染性、染色速度、表观染色深度远高于棉易产生染色不匀现象。     

直接染料对棉和大豆纤维的染色性能比较

测定了三种不同类型的直接染料在不同盐浓度和温度条件下对棉和大豆纤维的上染曲线，并对它们在这两种纤维上的染色性能进行了分析和比较。对于匀染型和温度效应型直接染料在大豆纤维上的上色率高于棉纤维；在不加盐的条件下，盐效应型染料上染率低于棉纤维，加盐后两者接近；提高温度，对匀染型染料影响不大，对温度效应型染料随温度的提高，上染率提高。     

稀土改性尼龙66纤维染色性能研究

采用对比的方法,对稀土改性尼龙66纤维和普通尼龙66纤维的染色性能进行了研究。结果发现:稀土改性尼龙66纤维的上染率明显高于普通尼龙66纤维,对于各种染料上染率一般提高10%-20%,而且上染速度也快得多。这种改性纤维染色的皂洗牢度等于成稍高于普通尼龙66纤维,而日晒牢度基本上没有变化。另外染色织物的色调略有一些变化。其原因在于:这种稀土改性尼龙68纤维中,稀土离子的作用使染料与纤维之间的作用力增大,使染料更易于上染到纤维上,而且结合牢度增强。     

仪纶染色动力学研究

根据传统的染色动力学理论,绘制不同颜色分散染料对仪纶的上染速率曲线,研究了三原色染料分散红HFW-4B、分散黄HFW-3R、分散蓝XFJJ对仪纶染色过程的动力学机理。结果表明,分散红染料上染仪纶纤维的染色速率常数最小,半染时间最长,扩散系数最低,但平衡吸附量最大,纤维易深染,而分散黄染料对仪纶的上染速率最快,但平衡吸附量最小,不易对纤维进行深染。     

Basofil纤维分散染料染色性能研究

选择了4只蒽醌结构和2只偶氮结构的分散染料，用于Basofil纤维的染色，用0.5molHCl和DMF在高温条件下将纤维上的染料萃取完全后、染料的最大吸收峰不变：在染色达到平衡时，测定了纤维上染料的浓度，结果显示：分子结构小、具有共平面的蒽醌染料适合上染Basofil纤维。染料的扩散系数和扩散活化能随染色温度上升而明显增加，其中C.I.Disperse Blue 56在纤维中扩散速度最快实验结果表明：染料的分子结构越小，染料上染量越大，扩散系数和扩散活化能的研究也揭示了相同的规律.     

聚乳酸纤维的硫化染料染色研究

本文采用C.I.硫化黑1对疏水性的聚乳酸纤维进行染色。实验发现,在2.0%色度下,染色纤维的颜色强度随分散剂用量的增加而得以提高,并在分散剂浓度达到6g/L时(浴比1:20),达到最大值;继续增加分散剂的用量导致颜色强度值下降。由于聚乳酸纤维的光学折射率低于聚酯纤维,因而在相同染色条件下,可以获得较高的颜色强度值。随着染色温度的提高,染色纤维的颜色强度值得以相应的提高,并在115℃时达到较高值;继续升高温度导致颜色强度值下降,这可能是由于染料分子的聚集引起的。染料对聚乳酸纤维的提升效果不明显,可能是因为染料与聚乳酸纤维之间亲和力不高所致。     

聚对苯二甲酸丁二酯纤维在超临界二氧化碳介质中的染色研究

用超临界二氧化碳作介质，在40～120℃，10～30MPa条件下使用分散染料对聚对苯二甲酸丁二酯(PBT)纤维进行染色试验，并测定了3种分散染料在超临界二氧化碳介质中的溶解度。研究了染色温度、压力、时间及染料结构对染料上染量的影响，考察了染料溶解度与染料上染量的关系。试验表明，在80℃，20MPa下，染色30min，PBT纤维能得到良好的染色效果，上染量达4．01mg/g(分散红60)、2．43mg／g(分散黄23)、11．19mg/g(分散蓝79)。     

涤/锦超细纤维无纺布染色研究

选用TERASIL分散染料对PET/PA超细纤维无纺布进行染色,从染料的相容性、提升性和上染率等方面对染色性能进行研究。结果显示TERASIL分散染料染PET/PA超细纤维上染百分率高、得色深、色牢度较高;染色条件为染色温度100℃,染色保温时间40分钟,染料用量可在4%以内。     

Dyeing fine denier polypropylene fibers with phenylazo- β -naphthol-containing sulfonamide disperse dyes

A series of phenylazo-β-naphthol-containing sulfonamide disperse dyes were prepared from C.I. Acid Orange 7 by successive reactions of chlorination and amination, and their chemical structures were characterized by FTIR, ¹H NMR, and mass spectrometry. The dyes were applied to coloring of knitted fabrics from fine denier polypropylene fibers by exhaust dyeing and their optimal dyeing conditions, such as dyebath pH, dyeing temperature, dyeing time, and dye concentration were investigated in detail. Then, dye exhaustion, color strength, and color fastnesses of the dyes on the fibers were assessed and summarized. In view of dye exhaustion and color strength of the sulfonamide dyes on fine denier PP fabrics, 90°C was selected as the best dyeing temperature at dye concentration below or equal to 3.0% owf. For achieving higher color strength, 130°C was the better choice when the dye concentration was above 3.0% owf. The sulfonamide dyes, especially secondary sulfonamide dyes, exhibited superior dye exhaustion and color fastnesses to washing, sublimation, and rubbing on fine denier PP fabrics in comparison to C.I. Solvent Yellow 14 bearing the same chromophore but without sulfonamide group.     

Dyeing fine denier polypropylene fibers with phenylazo-β-naphthol-containing sulfonamide disperse dyes

A series of phenylazo-β-naphthol-containing sulfonamide disperse dyes were prepared from C.I. Acid Orange 7 by successive reactions of chlorination and amination, and their chemical structures were characterized by FTIR, ¹H NMR, and mass spectrometry. The dyes were applied to coloring of knitted fabrics from fine denier polypropylene fibers by exhaust dyeing and their optimal dyeing conditions, such as dyebath pH, dyeing temperature, dyeing time, and dye concentration were investigated in detail. Then, dye exhaustion, color strength, and color fastnesses of the dyes on the fibers were assessed and summarized. In view of dye exhaustion and color strength of the sulfonamide dyes on fine denier PP fabrics, 90°C was selected as the best dyeing temperature at dye concentration below or equal to 3.0% owf. For achieving higher color strength, 130°C was the better choice when the dye concentration was above 3.0% owf. The sulfonamide dyes, especially secondary sulfonamide dyes, exhibited superior dye exhaustion and color fastnesses to washing, sublimation, and rubbing on fine denier PP fabrics in comparison to C.I. Solvent Yellow 14 bearing the same chromophore but without sulfonamide group.     

Dyeing fine denier polypropylene fibers with phenylazo-<Emphasis Type="Italic">β</Emphasis>-naphthol-containing sulfonamide disperse dyes

A series of phenylazo-β-naphthol-containing sulfonamide disperse dyes were prepared from C.I. Acid Orange 7 by successive reactions of chlorination and amination, and their chemical structures were characterized by FTIR, ¹H NMR, and mass spectrometry. The dyes were applied to coloring of knitted fabrics from fine denier polypropylene fibers by exhaust dyeing and their optimal dyeing conditions, such as dyebath pH, dyeing temperature, dyeing time, and dye concentration were investigated in detail. Then, dye exhaustion, color strength, and color fastnesses of the dyes on the fibers were assessed and summarized. In view of dye exhaustion and color strength of the sulfonamide dyes on fine denier PP fabrics, 90°C was selected as the best dyeing temperature at dye concentration below or equal to 3.0% owf. For achieving higher color strength, 130°C was the better choice when the dye concentration was above 3.0% owf. The sulfonamide dyes, especially secondary sulfonamide dyes, exhibited superior dye exhaustion and color fastnesses to washing, sublimation, and rubbing on fine denier PP fabrics in comparison to C.I. Solvent Yellow 14 bearing the same chromophore but without sulfonamide group.     

Effect of Sandospace R on the dyeability of gamma-irradiated wool,wool/polyester and polyester fabrics with some disperse dyes containing amino groups

The effect of Sandospace R on the dyeability of gamma-irradiated wool, wool/polyester and polyester fabrics towards disperse dyes has been investigated. The effects of the different factors that may affect the colour yield of the dyed samples (such as radiation dose, Sandospace R concentration, pH strength of the dye bath, dye concentration, dyeing temperature and time were studied. In general, and regardless of the studied factor, the irradiated fabric showed a significant dye affinity for the disperse dyes employed compared/to the unirradiated fabrics. However, the different fabrics irradiated to a dose of 2Mrad showed the highest colour strength with a high level of dyeing. Also, it was observed that a concentration of Sandospace R as low as 0·5% effectively enhances the dye affinity for the disperse dyes used here. Moreover, it was found that the pH of the dyeing bath at which the highest colour strength obtained was 3. Increasing the dye concentration up to 4% based on fabric weight, caused a significant enhancement in the colour strength, whilst raising/the dyeing bath temperature from 60°C to 100°C appreciably accelerated the rate of dye uptake. Complete exhaustion absorption of the disperse dye occurred over a period of 2h. © 1998 Society of Chemical Industry     

BS-RR型活性染料用于纤维素纤维染色和性能研究

通过探究环保型活性染料三原色BS-RR型各染料的上色性能、固色性能,得到并计算出染色特性参数值:直接性S、吸尽率E、固色率F及反应速率R;通过探究工艺参数:电解质用量、碱剂用量、温度、时间、浴比对染料上色及固色性能的影响,发现活性染料三原色BS-RR型具有宽泛的工艺宽容性,非常高的配伍性和移染指数MI来保证用活性染料染色的一次成功率,尤其适合小浴比染色,具有节能减排的经济性。     

Dyeing kinetics of methacrylic acid grafted polyester fabric with astrazonrot violet and rhodamine red basic dyes

The low‐temperature dyeing kinetics of radiation‐grafted poly(ethylene terephthalate) fabric were studied. The effects of the graft yield (GY), dye concentration, and dyeing temperature on the color difference (CD) of methacrylic acid grafted polyester fabric were studied for astrazonrot violet (AV) and rhodamine red (RR) basic dyes. CD increased sharply with an increase in GY and tended to level off at higher degrees of grafting. The best dyeing conditions were achieved for both dyes at pH 11.5. CD of the grafted fabric increased rapidly as the dyeing time increased; this was followed by a relatively slow dyeing rate within a few minutes, which depended on the concentration and temperature of the dye bath. The initial dyeing rates and rate constants for the AV dye were higher than those for the RR dye. The dyeing process followed 0.14‐order kinetics and was independent of the dyeing temperature or the type of dye. The dyeing rates and rate constants increased with an increase in the dyeing temperature. An Arrhenius‐type plot of the natural logarithm of the dyeing rate constant versus the inverse of the absolute temperature yielded apparent activation energies of 4.9 and 13.8 kJ/mol and pre‐exponential rate constants of 9.4 and 100.6 (CD/GY)s^?1 for the AV and RR dyes, respectively. The mechanism of the dyeing process for the two dyes was diffusion‐controlled, and their dyeing rates depended on the type of basic dye. © 2004 Wiley Periodicals, Inc. J Appl Polym Sci 94: 1070–1076, 2004     

分散染料可染丙纶的染色工艺

对影响分散染料可染丙纶上色率的染液浓度、浴比、固色时间、温度等工艺条件进行了试验 ,得到了较佳的染色工艺 :染液浓度 1.0 % (对织物质量 )、固色时间 90 min、温度 10 5℃、浴比 1∶ 5 0 ;分散染料可染丙纶长丝的上色率高于 PP/PET织物上色率。     

One‐bath union dyeing of a modified wool/acrylic blend with acid and reactive dyes

Pretreated wool/acrylic fibre was obtained by a facile amidoximation process. Fibre characterisation (nitrogen content, tensile strength, shrinkage, infrared spectra and X‐ray diffraction) proved the success of the pretreatment. Union dyeing of wool/acrylic fabrics with acid and reactive dyes, namely CI Acid Red 40, CI Acid Blue 25, CI Reactive Red 194 and CI Reactive Blue 25, was obtained using a one‐bath dyeing process. Different factors that may affect the dyeability of the blend fibre, such as dyebath pH, liquor ratio, temperature, time and dye concentration, were evaluated with respect to the dye exhaustion, fixation, colour strength, levelling and fastness properties. Excellent to good fastness was obtained for all samples, irrespective of the dye used. The result of the investigation offers a new viable method for union dyeing of wool/acrylic fibres in a one‐dyebath process.     

The Impact of Nitrogen Plasma Treatment upon the Physical-Chemical and Dyeing Properties of Wool Fabric

Pretreatment of wool fabric with low-temperature plasma (LTP) as an eco-friendly process was tested. The impact of plasma-treatment parameters on the surface morphology, physical-chemical, and dyeing properties of wool using anionic dyes were investigated. The LTP-treatment resulted in a dramatic improvement in fabric hydrophilicity and wettability, the removal of fiber surface material, and creation of new active sites along with improved initial dyeing rate. The nature of the plasma gas governed the final exhaustion percentage of the used acid dyes according to the following descending order: nitrogen plasma > nitrogen/oxygen (50/50) plasma > oxygen plasma > argon plasma ≥ control. Prolonging the exposure time up to 20 minutes resulted in a gradual improvement in the extent of exhaustion. Increasing the ageing period up to 100 hours resulted in a slight decrease in the extent of acid dye uptake. Increasing the salt concentration up to 5 g/L and the dyeing temperature up to 95°C resulted in an enhancement in the extent of exhaustion. The extent of improvement in dye bath exhaustion, using low temperature nitrogen plasma (LTNP)-treatment, was determined by the nature of the anionic dyes.     

活性染料无盐无碱染色研究

通过对活性染料染色整理一浴的工艺条件进行分析,得出最佳的染色工艺条件:浸轧(80%轧余率)→堆置(18小时~24小时)→烘干(100℃×3分钟)→焙烘(160℃×3.5分钟)→后处理。筛选出了适合染色整理一浴的活性染料:活性翠蓝、活性红HE-7B、活性黄HE-4G、活性红HE-3B。同时不仅考虑了染料浓度对皂洗后染料的提升性能、染料浓度对织物物理性能的影响,还分析了不同有机硅油柔软剂对织物的折皱恢复角和撕破强力的影响,得出用20g/L的柔软剂T689较适合该工艺。