Influence of Plain, Twill, and Satin Weave Structures on the Optimum Colorfastness Properties of Reactive Dyes
DOI:
https://doi.org/10.48048/tis.2021.83Keywords:
Colorfastness, Cellulose, Woven fabrics, Reactive dyes, Cover factorAbstract
The objective of this work is to study the influence of the plain, twill and satin weave structures on the colorfastness properties of reactive dyes. From the results, it can be concluded that plain weave fabric showed the optimum colorfastness properties due to its compact interlacement structure compared to twill and satin weave fabrics. Three types of plain, twill, and satin weave fabrics of different weave structures and weights (g/m2) were used in this research. The dyes, auxiliaries, and chemicals were applied, and the colorfastness tests were carried out in accordance with the test methods provided by ASTM and AATCC standards. Color strength (K/S) values were obtained using a reflectance spectrophotometer. A projection microscope was used to take cross sectional diagrams of the yarns for assessment. FTIR instrument transmitted infrared radiation to the dyed samples of up to a few microns to measure the spectroscopy within the visible spectral province with the maximum infrared ray (IR) peak values. The peak values of the FTIR device assured the presence of colorant or chromophore existing in the dyestuffs which were liable to expose the best colorfastness properties. This research is experimentally-based, and the findings are useful to personnel involved in cellulose fabric dyeing with reactive dyes and to the control of color properties. This research opens potential ways for scholars to advance study in this field.
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A Rehman, A Ahmad, A Hameed, S Kiran and T Farooq. Green dyeing of modified cotton fabric with Acalypha wilkesiana leave extracts. Sustain. Chem. Pharm. 2021; 21, 100432.
DN Zaghloul, TA Elmaaty, K Nakamura, I Tabata, T Hori and K Hirogaki. Influence of additive organic base on dyeing of cotton fabric under supercritical carbon dioxide using fluorotriazine reactive disperse dye and investigation of optimal dyeing conditions. J. Supercrit. Fluid. 2021; 174, 105243.
UH Siddiqua, S Ali, S Muzaffar, Z Subhani, M Iqbal, H Daud, DN Iqbal and A Nazir. Hetero-functional azo reactive dyes applied on cellulosic fabric and dyeing conditions optimization to enhance the dyeing properties. J. Eng. Fibers Fabrics 2021; 16, 1-12.
L Pei, Y Luo, MA Saleem and J Wang. Sustainable pilot scale reactive dyeing based on silicone oil for improving dye fixation and reducing discharges. J. Cleaner Prod. 2021; 279, 123831.
S Islam, SMM Alam and S Akter. Influence of thermal conduction on the stretching behavior of core spandex cellulosic fabrics. Mater. Today Proc. 2021; 38, 2563-71.
S Islam, SMM Alam and S Akter. 2021. Identifying the amount of heat flux and thermal conduction through fabrics with appropriate heat equation. Comput. Eng. Phys. Model. 4, 53-67.
IWK Suryawan, G Prajati, AS Afifah and MR Apritama. NH3-N and COD reduction in Endek (Balinese textile) wastewater by activated sludge under different DO condition with ozone pretreatment. Walailak J. Sci. & Tech. 2021; 18, 9127.
A Rehman, K Iqbal, F Azam, F Safdar, M Ashraf, HS Maqsood and A Basit. To enhance the dyeability of cotton fiber with the application of reactive dyes by using chitosan. J. Textil. Inst. 2020; 112, 1208-12
M Wang, C Guo, C Li and T Zhao. Design of novel reactive dyes containing cationic groups: Mechanism and application for environmentally friendly cotton dyeing. Fibers Polym. 2020; 21, 2848-60.
S Islam, SMM Alam and S Akter. Investigation of the colorfastness properties of natural dyes on cotton fabrics. Fibers Textil. 2020; 27, 58-68.
S Islam, SMM Alam and S Ahmed. Attaining optimum values of colourfastness properties of sustainable dyes on cotton fabrics. Fibres Textil. E. Eur. 2020; 28, 110-7.
S Islam, SMM Alam and S Akter. Mathematical investigation of the thermal conductivity of fabrics using thermal equation. Mater. Today Proc. 2021; 46, 413-24.
N Nadeem, M Zahid, A Tabasum, A Mansha, A Jilani, IA Bhatti and HN Bhatti. Degradation of reactive dye using heterogeneous photo-Fenton catalysts: ZnFe2O4 and GO-ZnFe2O4 composite. Mater. Res. Express 2020; 7, 015519.
F An, K Fang, X Liu, C Li, Y Liang and H Liu. Rheological properties of carboxymethyl hydroxypropyl cellulose and its application in high quality reactive dye inkjet printing on wool fabrics. Int. J. Biol. Macromol. 2020; 164, 4173-82.
S Wang, J Liu, L Sun, H Wang, P Zhu and C Dong. Preparation of flame-retardant/dyed cotton fabrics: Flame retardancy, dyeing performance and flame retardant/dyed mechanism. Cellulose 2020; 27, 10425-40.
F Parvin, S Islam, Z Urmy and S Ahmed. A study on the textile materials applied in human medical treatment. Eur. J. Physiother. Rehabil. Stud. 2020; 1, 56-80.
W Dechapanya, K Intawong and S Jawjit. Synthesis and characterization of TTIP-Al films and Fe3+/TTIP-Al films to be used in photocatalytic oxidation under visible light. Walailak J. Sci. & Tech. 2021; 18, 6551.
M Chairat. Thermodynamics study of lac dyeing of silk yarn coated with chitosan. Walailak J. Sci. & Tech. 2009; 6, 93-107.
A Milašius and V Milašius. New representation of the fabric weave factor. Fibres Textil. E. Eur. 2008; 16, 48-51.
D Shu, K Fang, X Liu, Y Cai, F An, G Qu and Y Liang. Cleaner pad-steam dyeing technology for cotton fabrics with excellent utilization of reactive dye. J. Cleaner Prod. 2009; 241, 118370.
S Islam. Attaining optimum strength of cotton-spandex woven fabric by apposite heat-setting temperature. J. Inst. Eng. (India) C 2009; 100, 601-6.
L Liu, B Mu, W Li and Y Yang. Cost-effective reactive dyeing using spent cooking oil for minimal discharge of dyes and salts. J. Cleaner Prod. 2009; 227, 1023-34.
L Liu, B Mu, W Li and Y Yang. Sustainable emulsion system based on spent cooking oil for pilot-scale reactive dyeing with minimal discharges. ACS Sustain. Chem. Eng. 2019; 7, 13698-707.
SMS Islam, M Alam and S Akter. Identifying the values of whiteness index, strength and weight of cotton spandex woven fabric in peroxide bleaching of different concentration. Fibers Textil. 2019; 4, 96-107.
S Islam, SMM Alam and S Akter. The consequences of temperature on the shrinkage properties of cotton spandex woven fabric. J. Textil. Polymer. 2019; 7, 25-29.
S Islam, S Ahmed, M Arifuzzaman, AKMS Islam and S Akter. Relationship in between strength and polyester content percentage of cotton polyester blended woven fabrics. Int. J. Clothing Sci. 2019; 6, 1-6.
S Islam, SMM Alam and S Akter. Identifying a suitable heat setting temperature to optimize the elastic performances of cotton spandex woven fabric. Res. J. Textil. Apparel 2018; 22, 260-70.
M Sadeghi-Kiakhani, AR Tehrani-Bagha and S Safapour. Enhanced anti-microbial, anti-creasing and dye absorption properties of cotton fabric treated with chitosan-cyanuric chloride hybrid. Cellulose 2018; 25, 883-93.
S Islam and SMM Alam. Investigation of the acoustic properties of needle punched nonwoven produced of blend with sustainable fibers. Int. J. Clothing Sci. Tech. 2018; 30, 444-58.
D Shu, K Fang, X Liu, Y Cai, X Zhang and J Zhang. Cleaner coloration of cotton fabric with reactive dyes using a pad-batch-steam dyeing process. J. Cleaner Prod. 2018; 196, 935-42.
M Zahid, IA Bhatti, S Adeel and S Saba. Modification of cotton fabric for textile dyeing: Industrial mercerization versus gamma irradiation. J. Textil. Inst. 2017; 108, 287-92.
UH Siddiqua, S Ali, M Iqbal and T Hussain. Relationship between structure and dyeing properties of reactive dyes for cotton dyeing. J. Mole. Liq. 2017; 241, 839-44.
MAR Bhuiyan, A Shaid, MM Bashar and P Sarkar. Investigation on dyeing performance of basic and reactive dyes concerning jute fiber dyeing. J. Nat. Fibers 2016; 13, 492-501.
KH Prabhu and AS Bhute. Plant based natural dyes and mordants: A review. J. Nat. Prod. Plant Resour. 2012; 2, 649-64.
D Stawski and J Szumilewicz. Formation of interpolymer complexes on polypropylene textiles via layer-by-layer modification as revealed by FTIR method. Walailak J. Sci. & Tech. 2012; 9, 165-71.
AS Belal. Understanding textiles for a merchandiser. BMN3 Foundation, Dhaka, 2009.
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