<p>The textile sector in Bangladesh, heavily reliant on resource-intensive exhaust dyeing, faces urgent sustainability challenges, including excessive water consumption, salt pollution, and high energy demand. This study evaluates the eco-efficient Cold Pad Batch (CPB) method as a scalable alternative to conventional exhaust dyeing for 100% cotton single jersey fabrics, benchmarking its performance. Results demonstrate the transformative potential of CPB: it achieved an average dye fixation of 82.5% without salt additives at ambient temperature. Calorimetrically, CPB matched exhaust dyeing in shade fidelity where ΔE &lt; 1.0 across all colors, while enhancing color strength for red and blue dyes. 1–2 levels improve the light fastness of CPB compared to traditional methods, and 0.5-1 levels enhance its wet friction fastness. Material characterization revealed the gentler processing of CPB. SEM showed smoother fiber surfaces, EDS confirmed negligible sodium residues validating salt-free operation, and XRD indicated reduced crystallinity disruption. By eliminating salt and thermal energy use, CPB mitigates effluent pollution and aligns with the sustainability imperatives of the country.</p> Graphical Abstract <p></p>

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Characterization and dyeing performance of cold pad batch method using reactive dyes

  • Mohammad Abdul Jalil,
  • Mehedi Hasan Chaion,
  • Md. Moniruzzaman,
  • Md. Ismail Hossain,
  • Abdus Salam,
  • Tarikul Islam,
  • Md. Matiar Rahman

摘要

The textile sector in Bangladesh, heavily reliant on resource-intensive exhaust dyeing, faces urgent sustainability challenges, including excessive water consumption, salt pollution, and high energy demand. This study evaluates the eco-efficient Cold Pad Batch (CPB) method as a scalable alternative to conventional exhaust dyeing for 100% cotton single jersey fabrics, benchmarking its performance. Results demonstrate the transformative potential of CPB: it achieved an average dye fixation of 82.5% without salt additives at ambient temperature. Calorimetrically, CPB matched exhaust dyeing in shade fidelity where ΔE < 1.0 across all colors, while enhancing color strength for red and blue dyes. 1–2 levels improve the light fastness of CPB compared to traditional methods, and 0.5-1 levels enhance its wet friction fastness. Material characterization revealed the gentler processing of CPB. SEM showed smoother fiber surfaces, EDS confirmed negligible sodium residues validating salt-free operation, and XRD indicated reduced crystallinity disruption. By eliminating salt and thermal energy use, CPB mitigates effluent pollution and aligns with the sustainability imperatives of the country.

Graphical Abstract