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667.3 : Teinture et impression des tissus 667.1 Nettoyage
667.2 Colorants et pigments 667.4 Encres 667.5 Encres d'imprimerie 667.6 Peintures 667.7 Cires, laques, vernis 667.9 Revêtements et enduits |
Ouvrages de la bibliothèque en indexation 667.3
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Ozone utilisation for discharge printing of reactive dyed cotton / Idil Yigit in COLORATION TECHNOLOGY, Vol. 134, N° 1 (02/2018)
[article]
Titre : Ozone utilisation for discharge printing of reactive dyed cotton Type de document : texte imprimé Auteurs : Idil Yigit, Auteur ; Semiha Eren, Auteur ; Hüseyin Aksel Eren, Auteur Année de publication : 2018 Article en page(s) : p. 13-23 Note générale : Bibliogr. Langues : Anglais (eng) Catégories : Coton Le coton est une fibre végétale qui entoure les graines des cotonniers "véritables"(Gossypium sp.), un arbuste de la famille des Malvacées. Cette fibre est généralement transformée en fil qui est tissé pour fabriquer des tissus. Le coton est la plus importante des fibres naturelles produites dans le monde. Depuis le XIXe siècle, il constitue, grâce aux progrès de l'industrialisation et de l'agronomie, la première fibre textile du monde (près de la moitié de la consommation mondiale de fibres textiles).
Impression sur étoffes
Ozone
Produits chimiques -- Suppression ou remplacement
Résistance à l'abrasion
Résistance au lavage
Teinture -- Fibres textilesIndex. décimale : 667.3 Teinture et impression des tissus Résumé : Environmental pollution is one of the major concerns of the textile finishing sector. The reduction or substitution of the harsh chemicals used during dyeing and printing processes is necessary. In this study, the use of ozone for the discharge printing process was examined in order to substitute the use of reductive agent and caustic soda by ozone gas. The reactive dyed cotton samples were wetted by water and some selected solutions at 25%, 40% and 60% pick up were used and subjected to ozone gas treatment. The gas flow rates were 5 and 10 l/min for 5 and 10 min treatment times, respectively. The results were compared with that of conventional discharge printed samples. Colour discharge (%), colour difference (ΔE), strength, washing and rubbing fastness and chemical oxygen demand (COD) values were compared and reported. Colour discharge increased at higher gas flow rates and prolonged treatment times. Although ozone printing could not attain the contour sharpness of conventional discharge printing, the addition of selected chemicals affected colour discharge and the contour sharpness. Strength tests did not show a significant decrease when using ozone treatment. Fastness tests results (washing and rubbing) were slightly higher compared with conventional discharge printed samples. COD values were much lower for ozone treatment compared with conventional discharge printing effluent. Consequently, it was demonstrated that ozone may be an environmentally friendly substitute for discharge printing. Note de contenu : - Visual comparison
- Colour discharge
- Wash and rub fastness of the samples
- Strength of the samples
- COD evaluationDOI : 10.1111/cote.12306 En ligne : https://onlinelibrary.wiley.com/doi/epdf/10.1111/cote.12306 Format de la ressource électronique : Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=30123
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Code-barres Cote Support Localisation Section Disponibilité 19649 - Périodique Bibliothèque principale Documentaires Disponible Pad dyeing of cellulose acetate nanofibres with disperse dyes / Zeeshan Khatri in COLORATION TECHNOLOGY, Vol. 129, N° 2 (04/2013)
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Titre : Pad dyeing of cellulose acetate nanofibres with disperse dyes Type de document : texte imprimé Auteurs : Zeeshan Khatri, Auteur ; Awais Khatri, Auteur ; Umaima Saleem, Auteur ; Gopiraman Mayakrishnan, Auteur ; Byoung-Suhk Kim, Auteur ; Kai Wei, Auteur ; Ick-Soo Kim, Auteur Année de publication : 2013 Article en page(s) : p. 159-163 Note générale : Bibliogr. Langues : Anglais (eng) Catégories : Acétate de cellulose L'acétate de cellulose est une matière plastique inventée en 1865. C'est l'ester acétate de la cellulose.
Colorants réactifs
Elasticité
Electrofilature
Fibres cellulosiques
Nanofibres
Teinture -- Fibres textilesIndex. décimale : 667.3 Teinture et impression des tissus Résumé : In addition to a number of applications of nanofibres in technical fields such as medical, filtration and biosensing, nanofibres are recently being widely explored in terms of apparel use. Past work has focused on the functional properties of nanofibres for apparel use. Coloured nanofibres were produced to investigate their aesthetic properties for the potential application to apparel. Webs of cellulose acetate nanofibre were electrospun and dyed with a high energy level CI Disperse Red 167:1 dye and a low energy level CI Disperse Blue 56 dye using the continuous pad–dry–bake method. Results revealed that the high energy level dye produced better colour yield than the lower energy level dye. The dyed cellulose acetate nanofibres produced acceptable colorimetric values, colour yield and colour fastness. Young’s modulus of dyed nanofibres increased by threefold in comparison to the undyed cellulose acetate nanofibres. Scanning electron microscopy images showed good morphology with the smooth surface of the dyed cellulose acetate nanofibres. Note de contenu : - EXPERIMENTAL : Materials - Electrospinning - Dyeing of nanofibres - Measurements
- RESULTS AND DISCUSSION : Effect of baking temperature - Effect of baking time - Effect of dye concentration - Colour fastness properties - Morphology of dyed cellulose acetate nanofibres - Mechanical propertyDOI : 10.1111/j.1478-4408.2012.00409.x Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=18060
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Code-barres Cote Support Localisation Section Disponibilité 14906 - Périodique Bibliothèque principale Documentaires Disponible Partitioning colour differences into dyers'components : the 'DBH'model / Ken J. Smith in COLORATION TECHNOLOGY, Vol. 123, N° 3 (2007)
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Titre : Partitioning colour differences into dyers'components : the 'DBH'model Type de document : texte imprimé Auteurs : Ken J. Smith, Auteur Année de publication : 2007 Article en page(s) : p. 170-177 Note générale : Bibliogr. Langues : Anglais (eng) Index. décimale : 667.3 Teinture et impression des tissus Résumé : Mathematics are given for a method of converting the cylindrical components of colour differences reported by colour measurement systems (differences in lightness, chroma and hue) into components that are correlates of those naturally used by dyers during visual assessment (differences in depth, brightness and hue). The history of the development of the method is recorded. The method has been in successful routine use by many organisations throughout the dye-making, dyeing and textile-finishing industries for more than 30 years but its mathematics have hitherto remained unpublished. DOI : 10.1111/j.1478-4408.2007.00075.x En ligne : http://onlinelibrary.wiley.com/doi/10.1111/j.1478-4408.2007.00075.x/pdf Format de la ressource électronique : Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=3540
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Code-barres Cote Support Localisation Section Disponibilité 007638 - Périodique Bibliothèque principale Documentaires Disponible Peracetic acid bleaching of banana fibre: Process optimisation / S. N. Chattopadhyay in COLORATION TECHNOLOGY, Vol. 139, N° 6 (12/2023)
[article]
Titre : Peracetic acid bleaching of banana fibre: Process optimisation Type de document : texte imprimé Auteurs : S. N. Chattopadhyay, Auteur ; Kartick K. Samanta, Auteur ; L. Ammayappan, Auteur ; R. K. Ghosh, Auteur Année de publication : 2023 Article en page(s) : p. 678-688 Note générale : Bibliogr. Langues : Anglais (eng) Catégories : Agents de blanchiment
Bananier et constituants
Fibres végétales -- Propriétés chimiques
Fibres végétales -- Propriétés physiques
Peracétique, AcideL'acide peracétique ou acide peroxyacétique (formule chimique: C2H4O3) (ou PAA) est un acide et agent oxydant très puissant utilisé dans l'Industrie pharmaceutique et le domaine médical comme oxydant, biocide désinfectant ou "stérilisant à froid" de certains dispositifs médicaux5. Ses propriétés oxydantes sont connues depuis 1902.
Cette molécule est très soluble dans l'eau, l'alcool et l'éther.
Fabrication : Il est le plus souvent produit en faisant agir de l'anhydre mixte boroacétique sur du peroxyde d'hydrogène (eau oxygénée).
Dégradation : En condition normale, ce produit se dégrade en sous-produits non toxiques (acide acétique, oxygène et eau).
Efficacité comme biocide : Utilisé seul ou avec du chlore ou des formaldehydes, sous forme liquide8 ou gazeuse (vapeur d'acide peracétique), il tue la plupart des micro-organismes libres en libérant de l'oxygène avec production d'hypochlorite ou de radicaux hydroxyles. Il est le plus efficace des désinfectants du marché sur les bactéries Gram-positives et Gram-négatives (moins de 5 minutes à faibles concentrations sur des bactéries libres), sur Mycobacterium tuberculosis et sur les spores.Index. décimale : 667.3 Teinture et impression des tissus Résumé : Banana is an important commercially available natural fibre, suitable for making coarse yarns. It has also potential for making fine home and apparel textiles after requisite chemical intervention or blending with other fine fibres. For making such products, chemical processing, namely bleaching, coloration and finishing, play an important role. Bleaching of fibre is generally carried out in highly alkaline condition and at high temperature of 85°C using hydrogen peroxide to achieve whiteness index of > 70 with about 25% loss in tensile strength. To achieve a similar whiteness index, while addressing strength loss, a fibre friendly low-temperature low-alkali based peracetic acid (PAA) bleaching of banana fibre has been proposed in the present article. Important bleaching process parameters, namely PAA concentration (10–30 g/L), time (60–180 min) and temperature (60–80°C), have been varied for optimisation of the bleaching process. Banana fibre bleaching using PAA concentration of 20 g/L at 70°C for 2 h can produce fibre with whiteness index of > 70, which is suitable for subsequent coloration. The PAA bleached banana fibre can retain 84% of its bundle strength and 95.6% of its weight. Physical (strength, fineness), chemical (attenuated total reflectance Fourier-transform infrared [ATR-FTIR], energy dispersive X-ray spectroscopy [EDX]), optical (colour) and morphological (scanning electron microscopy [SEM]) properties of banana fibres before and after bleaching were evaluated to study the efficacy of the process. Note de contenu : - EXPERIMENTAL : Materials - Chemicals - Mild scouring and peracetic acid bleaching - Fibre properties evaluation - Fibre physical and chemical properties
- RESULTS AND DISCUSSION : Properties of banana fibre - Bleaching of fibre - Physical and chemical properties in optimised condition
- Table 1 : Properties of banana fibre in comparison to jute
- Table 2 : Process variable for peracetic acid (PAA) bleaching of banana fibre
- Table 3 : Properties of scoured and bleached banana fibre in optimised condition
- Table 4 : Atomic percentage in the banana fibres before and after peracetic acid (PAA) bleachingDOI : https://doi.org/10.1111/cote.12681 En ligne : https://onlinelibrary.wiley.com/doi/epdf/10.1111/cote.12681 Format de la ressource électronique : Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=40119
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Code-barres Cote Support Localisation Section Disponibilité 24320 - Périodique Bibliothèque principale Documentaires Disponible Performance enhancement of one-bath pigment coloration and finishing process using eco-friendly crosslinkers / Muhammad Mohsin in COLORATION TECHNOLOGY, Vol. 137, N° 3 (06/2021)
[article]
Titre : Performance enhancement of one-bath pigment coloration and finishing process using eco-friendly crosslinkers Type de document : texte imprimé Auteurs : Muhammad Mohsin, Auteur ; Shaheen Sardar, Auteur ; Komal Iftikhar, Auteur Année de publication : 2021 Article en page(s) : p. 217-225 Note générale : Bibliogr. Langues : Anglais (eng) Catégories : Antimicrobiens
Bleu (couleur)
CotonLe coton est une fibre végétale qui entoure les graines des cotonniers "véritables"(Gossypium sp.), un arbuste de la famille des Malvacées. Cette fibre est généralement transformée en fil qui est tissé pour fabriquer des tissus. Le coton est la plus importante des fibres naturelles produites dans le monde. Depuis le XIXe siècle, il constitue, grâce aux progrès de l'industrialisation et de l'agronomie, la première fibre textile du monde (près de la moitié de la consommation mondiale de fibres textiles).
Imperméabilisation
Jaune
Oléofugation
Pigments
Résistance à l'abrasion
Résistance à la transpiration
Résistance au lavage
Résistance aux frottements humides
Résistance chimique
Réticulants
Rouge (couleur)
Teinture -- Fibres textiles
Textiles et tissus -- Propriétés mécaniquesIndex. décimale : 667.3 Teinture et impression des tissus Résumé : The one-bath pigment coloration and finishing process decreases the consumptions related to the energy, water, chemicals, labour, and production time as compared to the conventional two-bath application. Conventionally, pigment coloration uses binders, such as acrylic, for the attachment of the pigment onto the fabric. Then, the finishes are applied in a separate step. One-bath pigment coloration and finishing can solve this problem but the compatibility among the pigments, crosslinkers, and fabrics is critical and difficult to achieve. In addition, the performance of the fabric treated with one-bath application should match the performance of the fabric treated with the conventional two-bath coloration and finishing. To address such challenges, this article studies the performance of the one-bath pigment coloration and finishing using three primary colours, five crosslinkers, and an oil and water repellent finish in the pad-dry-cure process. The results show that all the formulas with the crosslinkers are comparable with each other as well as associated reference samples coloured with conventional acrylic binder. Nevertheless, the bio-based crosslinkers, citric acid and succinic acid, are more compatible and sustainable for the one-bath pigment coloration and finishing. The fastness properties, shrinkage, crease recovery angle, and oil and water repellency were also improved due to the one bath pigment coloration and finishing. Note de contenu : - EXPERIMENTAL : Materials and methods
- RESULTS AND DISCUSSION : Shade depth - Dry and wet rubbing fastness - Washing fastness - Perspiration fastness - Crease recovery angle - Shrinkage - Oil and water repellency - Flexural rigidity and tensile strength retention (%) - Soil release - Antimicrobial
- Table 1 : Pigment coloration and finishing alternative formulas
- Table 2 : Comparison of coloration results amongst untreated, dyed and one-bath coloration and finishing samples
- Table 3 : Crease recovery performance of the one-bath coloured and finished samples
- Table 4 : Shrinkage performance of the one-bath coloured and finished samples
- Table 5 : Oil repellency performance of the one-bath coloured and finished samples
- Table 6 : Flexural rigidity and tensile strength retention (%) of the one-bath coloured and finished samples
- Table 7 : Soil release of the one-bath coloured and finished samples
- Table 8 : Antimicrobial performance of the one-bath coloured and finished samplesDOI : https://doi.org/10.1111/cote.12522 En ligne : https://onlinelibrary.wiley.com/doi/epdf/10.1111/cote.12522 Format de la ressource électronique : Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=36088
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Code-barres Cote Support Localisation Section Disponibilité 22845 - Périodique Bibliothèque principale Documentaires Disponible Peroxidase-catalysed coloration of wool fabrics / Nalinee Netithammakorn in COLORATION TECHNOLOGY, Vol. 137, N° 2 (04/2021)
PermalinkPerspectives pour l'impression / Wilfried Kothe in L'INDUSTRIE TEXTILE, N° 1284 (02/1997)
PermalinkpH-responsive cotton fibre dyed by natural madder dye / Shilong Zhu in COLORATION TECHNOLOGY, Vol. 138, N° 3 (06/2022)
PermalinkPhoto-reductive fading of disperse azo dyes on nylon substrate: thermochemical analyses of reactions of photo-induced radicals using the semiempirical molecular orbital method / Yasuyo Okada in COLORATION TECHNOLOGY, Vol. 125, N° 6 (2009)
PermalinkPhotoassisted degradation of CI reactive red 195 using and Fe(III)-grafted polytetrafluoroethylene fibre complex as a novel heterogeneous Fenton catalyst over a wide pH range / Bing Li in COLORATION TECHNOLOGY, Vol. 129, N° 6 (12/2013)
PermalinkPhotofading of azo dyes : a theoretical study / Sandeep Tripathi in COLORATION TECHNOLOGY, Vol. 124, N° 3 (2008)
PermalinkPhotofading of phenylazo-aniline, -pyridone and -quinolone disperse dyes on a nylon 6 substrate / Yasuyo Okada in COLORATION TECHNOLOGY, Vol. 125, N° 2 (2009)
PermalinkPhysico-chemical treatment of indigo dye wastewater / B. Manu in COLORATION TECHNOLOGY, Vol. 123, N° 3 (2007)
PermalinkPhysicochemical investigation and spectral properties of sunset yellow dye in cetyltrimethylammonium bromide micellar solution under different pH conditions / Muhammad F. Nazar in COLORATION TECHNOLOGY, Vol. 130, N° 3 (06/2014)
PermalinkPigments extracted from the wood-staining fungi chlorociboria aeruginosa, scytalidium cuboideum, and S. ganodermophthorum show potential for use as textile dyes in COLORATION TECHNOLOGY, Vol. 130, N° 6 (12/2014)
PermalinkPlasma-photocatalytic degradation of dyeing wastewater : comparison of titanium oxide, zinc oxide, and graphene oxide / Doo Il Jang in COLORATION TECHNOLOGY, Vol. 130, N° 2 (04/2014)
PermalinkPoly(methyl methacrylate)/polysiloxane core-shell latex as a deepening agent for dyed polyester fabric / Chengbing Yu in COLORATION TECHNOLOGY, Vol. 135, N° 5 (10/2019)
PermalinkPolydopamine-coated silk yarn for improving the light fastness of natural dyes / Sanhanut Kesornsit in COLORATION TECHNOLOGY, Vol. 135, N° 2 (04/2019)
PermalinkPolymer- and wax-based monoconcentrate predispersed pigments in the colouring of plastics / Suresh P. Deshmukh in COLORATION TECHNOLOGY, Vol. 126, N° 4 (2010)
PermalinkPomegranate fallen leaves as a source of natural dye for mordant-free dyeing of wool / Aminoddin Haji in COLORATION TECHNOLOGY, Vol. 139, N° 2 (04/2023)
PermalinkPractical realisation of ozone clearing after disperse dyeing of polyester / Seda Gundogan in COLORATION TECHNOLOGY, Vol. 130, N° 5 (10/2014)
PermalinkPredicting the crease recovery performance and tear strength of cotton fabric treated with modified N-methylol dihydroxyethylene urea and polyethylene softener / Tanveer Hussain in COLORATION TECHNOLOGY, Vol. 126, N° 5 (2011)
PermalinkPrediction of depth of shade of a dyed polyester fabric based on fibre fineness and fabric structure / Shiqi Li in COLORATION TECHNOLOGY, Vol. 125, N° 5 (2009)
PermalinkPrediction of recipes for cotton cationisation and reactive dyeing to shade match conventionally dyed cotton / Matthew J. Farell in COLORATION TECHNOLOGY, Vol. 130, N° 5 (10/2014)
PermalinkPrediction of the photofading of 1-H or 1-ethyl derivatives of 3-cyano-6-hydroxy-4-methyl-5-(p-X-phenylazo)-2-pyridone dyes and their azo-hydrazone tautomerism: A theoretical study / Krzysztof Wojciechowski in COLORATION TECHNOLOGY, Vol. 139, N° 3 (06/2023)
PermalinkPrediction of the reactive dye recipe in cotton fabric dyeing using the pad-dry-pad-steam process by particle swarm optimisation-least squares support vector machine with matching database / Chengbing Yu in COLORATION TECHNOLOGY, Vol. 138, N° 6 (12/2022)
PermalinkPreparation and application of ultrahigh-pressure-homogenised aminosilicon-based softeners / Soon Chul Kwon in COLORATION TECHNOLOGY, Vol. 130, N° 3 (06/2014)
PermalinkPreparation and characterisation of novel phospholipid cationic liposomes to improve the alkaline hydrolysis and dyeability of polyester fabric / Manal M. El-Zawahri in COLORATION TECHNOLOGY, Vol. 129, N° 3 (06/2013)
PermalinkPreparation and photocatalytic activity of chitosan-supported cobalt phthalocyanine membrane / Rong-Min Wang in COLORATION TECHNOLOGY, Vol. 130, N° 1 (02/2014)
PermalinkPreparation and properties of Fe(II)-ion-sensitive colour-changing fabric / Jungxiong Lin in COLORATION TECHNOLOGY, Vol. 131, N° 2 (04/2015)
PermalinkPreparation of an ecofriendly chitosan–ZnO composite for chromium complex dye adsorption / Shanmugam Anandhavelu in COLORATION TECHNOLOGY, Vol. 129, N° 3 (06/2013)
PermalinkPreparation of cationic viscose and its salt-free dyeing using reactive dye / Yue Li in COLORATION TECHNOLOGY, Vol. 138, N° 4 (08/2022)
PermalinkPreparation of melamine-formaldehyde encapsulated fluorescent dye dispersion and its application to cotton fabric printing / Anran Hu in COLORATION TECHNOLOGY, Vol. 135, N° 2 (04/2019)
PermalinkPreparation of non-aggregating novel silicon phthalocyanines axially disubstituted with fluorinated functions / Zekeriya Biyiklioglu in COLORATION TECHNOLOGY, Vol. 129, N° 6 (12/2013)
PermalinkPreparation of pigmented ink-jet ink by a combination of surface treatments and synthetic dispersant / Chun Yoon in COLORATION TECHNOLOGY, Vol. 127, N° 3 (2011)
PermalinkPreparation of reactive nanoscale carbon black dispersion for pad coloration of cotton fabric / Cuiling Xu in COLORATION TECHNOLOGY, Vol. 134, N° 2 (04/2018)
PermalinkPreparation of thermally stable dyes derived from diketopyrrolopyrrole pigment by polymerisation with polyisocyanate binder / Chun Yoon in COLORATION TECHNOLOGY, Vol. 131, N° 1 (02/2015)
PermalinkPretreating poly(p-phenylene benzobisoxazole) fibre with polyphosphoric acid and dyeing with disperse dyes / Yu Guan in COLORATION TECHNOLOGY, Vol. 129, N° 5 (10/2013)
PermalinkPretreatment effects on pigment-based textile inkjet printing – colour gamut and crockfastness properties / Yi Ding in COLORATION TECHNOLOGY, Vol. 135, N° 1 (02/2019)
PermalinkPretreatment of cotton fabrics with polyamino carboxylic acids for salt-free dyeing of cotton with reactive dyes in COLORATION TECHNOLOGY, Vol. 129, N° 2 (04/2013)
PermalinkPretreatment of wool/polyester blended fabrics to enhance titanium dioxide nanoparticle adsorption and self-cleaning properties / Majid Montazer in COLORATION TECHNOLOGY, Vol. 127, N° 5 (2011)
PermalinkPrevention of biofouling on aquaculture nets with eco-friendly antifouling paint formulation / Korhan Sen in COLORATION TECHNOLOGY, Vol. 136, N° 2 (04/2020)
PermalinkPermalinkPrinting cotton fabrics with reactive dyes of high reactivity from an acidic printing paste / Yasser H. El Hamaky in COLORATION TECHNOLOGY, Vol. 123, N° 6 (2007)
PermalinkPrinting of antimicrobial microcapsules on textiles / Barbara Ocepek in COLORATION TECHNOLOGY, Vol. 128, N° 2 (2012)
PermalinkA process for dyeing cotton with direct dyes possessing primary aromatic amino groups furnishing wash fastness exhibited by reactive dyes / Pratik Hande in COLORATION TECHNOLOGY, Vol. 138, N° 3 (06/2022)
PermalinkProcess improvement and efficiency analysis using the Single-Minute Exchange of Dies method applied to the set-up and operation of screen-printing machines / Isabel Cabral in COLORATION TECHNOLOGY, Vol. 139, N° 2 (04/2023)
PermalinkProduction of dye nanoparticles via a supercritical gas anti-solvent process and optimisation of the process conditions / Mitra Amani in COLORATION TECHNOLOGY, Vol. 139, N° 6 (12/2023)
PermalinkProgrès réalisés dans le domaine de la technologie chimique des textiles. Progrès réalisés dans l'application des matières colorantes - Première partie / Louis Diserens / Paris : Editions Teintex (1956)
PermalinkProgress towards a greener textile industry / Tim Dawson in COLORATION TECHNOLOGY, Vol. 128, N° 1 (2012)
PermalinkProperties of differently printed and easy-care finished linen fabrics / Petra Forte Tavčer in COLORATION TECHNOLOGY, Vol. 127, N° 3 (2011)
PermalinkProperties of ink-jet printed, ultraviolet-cured pigment prints in comparison with screen-printed, thermo-cured pigment prints / Masenka Mikuz in COLORATION TECHNOLOGY, Vol. 126, N° 5 (2011)
PermalinkProperties of a new nitrogen-free additive as an alternative to urea and its application in reactive printing / Chenglong Wang in COLORATION TECHNOLOGY, Vol. 138, N° 2 (04/2022)
PermalinkProtection of lyocell against fibrillation. Part 2 : Application of 4,6-(p-B-sulphatoethylsulphonyl)anilino-1,3,5-triazin-2(1H)-one to lyocell by an exhaust process / I. Bates in COLORATION TECHNOLOGY, Vol. 123, N° 1 (2007)
PermalinkProtection of lyocell against fibrillation. Part 3 : Investigation of the durability of crosslinks formed with 4,6-(p-beta-sulphatoethylsulphonyl)-anilino-1,3, 5-triazin-2(1H)-one on lyocell fibre / I. Bates in COLORATION TECHNOLOGY, Vol. 123, N° 3 (2007)
PermalinkProtection of lyocell fibres against fibrillation ; influence of dyeing with bis-monochloro-s-triazinyl reactive dyes / I. Bates in COLORATION TECHNOLOGY, Vol. 124, N° 4 (2008)
PermalinkProtection of lyocell fibres against fibrillation ; mechanism for the poor crosslinking performance of reactive dyes on lyocell fibres and the influence of a colourless crosslinking agent as co-applicant / R. Ibbett in COLORATION TECHNOLOGY, Vol. 125, N° 2 (2009)
PermalinkPurification and characterization of three commercial phenylazoaniline disperse dyes / Gisela A. Umbuzeiro in COLORATION TECHNOLOGY, Vol. 133, N° 6 (12/2017)
PermalinkQuantitative structure–property relationship modelling for photoreduction-fast azo dyes on a nylon substrate : a methodology for thermochemical analysis of the photocleavage of azo dyes using the RM1 semi-empirical molecular orbital method / Yasuyo Okada in COLORATION TECHNOLOGY, Vol. 133, N° 2 (04/2017)
PermalinkRadical mechanism of azo cleavage for monoazo reactive dyes, a QSPR study : the similarity between photoreduction on polyamide substrates and thermal reduction in aqueous dithionite solutions / Yasuyo Okada in COLORATION TECHNOLOGY, Vol. 132, N° 4 (08/2016)
PermalinkReactive dyeing of silk using commercial acid dyes based on a three-component Mannich-type reaction / Qing Guo in COLORATION TECHNOLOGY, Vol. 136, N° 4 (08/2020)
PermalinkReactive dyes for living cells : Applications, artefacts, and some comparisons with textile dyeing / Richard W. Horobin in COLORATION TECHNOLOGY, Vol. 138, N° 1 (02/2022)
PermalinkReactive dyes for textile fibres / A. Hunter M. Renfrew / Bradford [United Kingdom] : Society of Dyers and Colourists (1999)
PermalinkRealisation of polyester fabrics with low transmission for ultraviolet light / Mohammad Toufiqul Hoque in COLORATION TECHNOLOGY, Vol. 136, N° 4 (08/2020)
PermalinkRecent advances in supercritical fluid dyeing / Mauro Branchero in COLORATION TECHNOLOGY, Vol. 136, N° 4 (08/2020)
PermalinkRecipe formulation based on spectral visual response fitting / Guoxing He in COLORATION TECHNOLOGY, Vol. 125, N° 3 (2009)
PermalinkRecueil de normes françaises : textiles, tome 4 / Association Française de Normalisation (Paris) / Saint-Denis La Plaine : Association Française de Normalisation (AFNOR) (1985)
PermalinkReduced angle sensitivity of structural coloration on an industrial aluminium platform / Rachel Odessey in COLORATION TECHNOLOGY, Vol. 136, N° 3 (06/2020)
PermalinkRelations entre le comportement des couleurs d'impression au vaporisage et leurs caractéristiques physico-chimiques / Marc Olivier
PermalinkRelationship between colour fastness and colour strength of polypropylene fabrics dyed in supercritical carbon dioxide: effect of chemical structure in 1,4-bis(alkylamino)anthraquinone dyestuffs on dyeing performance / Keisuke Miyazaki in COLORATION TECHNOLOGY, Vol. 128, N° 1 (2012)
PermalinkRelationship between photofading and chemical structure of disperse azo dyes on nylon fabric / Yasuyo Okada in COLORATION TECHNOLOGY, Vol. 126, N° 4 (2010)
PermalinkRemoval of aromatic amines and decolourisation of azo dye baths by electrochemical treatment / Víctor López-Grimau in COLORATION TECHNOLOGY, Vol. 129, N° 4 (08/2013)
PermalinkRemoval of Erioglaucine (Acid Blue 9) with a new coagulant agent from Acacia mearnsii tannin extract / Jesùs Sànchez Martin in COLORATION TECHNOLOGY, Vol. 128, N° 1 (2012)
PermalinkRemoval of methylene blue from aqueous solutions by using cold plasma- and formaldehyde-treated onion skins / Cafer Saka in COLORATION TECHNOLOGY, Vol. 127, N° 4 (2011)
PermalinkRemoval of reactive dyes from wastewater by acrylate polymer beads bearing amino groups : isotherm and kinetic studies in COLORATION TECHNOLOGY, Vol. 129, N° 2 (04/2013)
PermalinkResearch in the cold pad–batch dyeing process for wool pretreated by hydrogen peroxide / Xue Zhao in COLORATION TECHNOLOGY, Vol. 125, N° 3 (2009)
PermalinkResearch of influences of surface structure of coloured textiles : applying fuzzy logic / Martinia Ira Glogar in COLORATION TECHNOLOGY, Vol. 127, N° 6 (2011)
PermalinkResistance variation of conductive ink applied by the screen printing technique on different substrates / Pedro Gomes in COLORATION TECHNOLOGY, Vol. 136, N° 2 (04/2020)
PermalinkReuse of ash-tree (Fraxinus excelsior L.) bark as natural dyes for textile dyeing : process conditions and process stability / Thomas Bechtold in COLORATION TECHNOLOGY, Vol. 123, N° 4 (2007)
PermalinkReuse of textile wastewater treated by moving bed biofilm reactor coupled with membrane bioreactor / Xuefei Yang in COLORATION TECHNOLOGY, Vol. 137, N° 5 (10/2021)
PermalinkReuse of the water and salt of reactive dyeing effluent after electrochemical decolorisation / Víctor López-Grimau in COLORATION TECHNOLOGY, Vol. 128, N° 1 (2012)
PermalinkA review of organic electrochromic fabric devices / Whitney M. Kline in COLORATION TECHNOLOGY, Vol. 130, N° 2 (04/2014)
PermalinkReview of quantitative structure-activity/property relationship studies of dyes : recent advances and perspectives / Feng Luan in COLORATION TECHNOLOGY, Vol. 129, N° 3 (06/2013)
PermalinkReview of the process development aspects of electrochemical dyeing: its impact and commercial applications / Manickam Anbu Kulandainathan in COLORATION TECHNOLOGY, Vol. 123, N° 3 (2007)
PermalinkReview of the textile coloration industry in Vietnam / Dang Tran Phong in COLORATION TECHNOLOGY, Vol. 124, N° 6 (2008)
PermalinkRevisiting the sublimation printability of cellulose-based textiles in light of ever-increasing sustainability issues / Ilhan Özen in COLORATION TECHNOLOGY, Vol. 138, N° 6 (12/2022)
PermalinkRheological studies of mixed printing pastes from sodium alginate and modified xanthan and their application in the reactive printing of cotton / Lili Wang in COLORATION TECHNOLOGY, Vol. 130, N° 4 (08/2014)
PermalinkRole of quaternary ammonium salts in improving the fastness properties of anionic dyes on cellulose fibres / Saima Sharif in COLORATION TECHNOLOGY, Vol. 123, N° 1 (2007)
PermalinkRope dyeing of fabric in supercritical carbon dioxide for commercial purposes / Mu-Ying Yang in COLORATION TECHNOLOGY, Vol. 130, N° 2 (04/2014)
PermalinkA route from olive oil production to natural dyeing : valorisation of prina (crude olive cake) as a novel dye source / Özlenen Erdem Ismal in COLORATION TECHNOLOGY, Vol. 130, N° 2 (04/2014)
PermalinkA salt-free pad-irradiate-pad-steam reactive dyeing process for cotton fabric and the influence of cationising conditions on its coloration / Chengbing Yu in COLORATION TECHNOLOGY, Vol. 137, N° 4 (12/07/2021)
PermalinkSaturated steam-assisted radio frequency fixation of reactive printed cotton fabrics / Arzu Yavas in COLORATION TECHNOLOGY, Vol. 127, N° 3 (2011)
PermalinkSelf-cleaning bombyx mori silk : room-temperature preparation of anatase nano-TiO2 by the sol-gel method and its application / Chenghui Zheng in COLORATION TECHNOLOGY, Vol. 130, N° 4 (08/2014)
PermalinkSignificance of dye research and development for practical dyers / James Park in COLORATION TECHNOLOGY, Vol. 123, N° 4 (2007)
PermalinkSimulation, synthesis, characterisation and dyeing properties of a fluorescent hemicyanine dye / Songsong Tang in COLORATION TECHNOLOGY, Vol. 136, N° 1 (02/2020)
PermalinkSimultaneous afterclearing and decolorisation by ozonation after disperse dyeing of polyester / Hüseyin Aksel Eren in COLORATION TECHNOLOGY, Vol. 123, N° 4 (2007)
PermalinkSimultaneous low-salt dyeing and anti-bacterial finishing of cotton fabric with reactive dye and N-halamine / Meng Zhang in COLORATION TECHNOLOGY, Vol. 137, N° 5 (10/2021)
PermalinkSingle-phase ink-jet printing onto cotton fabric / Soleimani-Gorgani Atasheh in COLORATION TECHNOLOGY, Vol. 129, N° 2 (04/2013)
PermalinkA single-step pad-steam cationisation and dyeing process for improving dyeing properties of cotton fabrics / Lei Wang in COLORATION TECHNOLOGY, Vol. 138, N° 5 (10/2022)
PermalinkSolubilisation kinetics of some monoazo naphthalimide disperse dyes containing butyric acid and investigation of fastness properties of the dyes on polyester / Kamaladin Gharanjig in COLORATION TECHNOLOGY, Vol. 126, N° 1 (2010)
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