Academic literature on the topic 'Produits chimiques textiles – Recyclage'
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Journal articles on the topic "Produits chimiques textiles – Recyclage":
Mansour, Hedi Ben, Oualid Boughzala, dorra Dridi, Daniel Barillier, Leila Chekir-Ghedira, and Ridha Mosrati. "Les colorants textiles sources de contamination de l’eau : CRIBLAGE de la toxicité et des méthodes de traitement." Revue des sciences de l’eau 24, no. 3 (November 28, 2011): 209–38. http://dx.doi.org/10.7202/1006453ar.
Sotomayor, O. A. Z., S. W. Park, and C. Garcia. "Modèle de référence pour évaluer différentes stratégies de contrôle dans des usines de traitement des eaux usées." Revue des sciences de l'eau 15, no. 2 (April 12, 2005): 543–56. http://dx.doi.org/10.7202/705468ar.
Serpa, Nilo. "Sur l'Entropie Contrôlée des Systèmes: Transformations de la Matière Condensée (On the Controlled Entropy of the Systems: Condensed Matter Transformations)." CALIBRE - Revista Brasiliense de Engenharia e Física Aplicada 3 (June 17, 2018). http://dx.doi.org/10.17648/calibre.v3i.372x.
Dissertations / Theses on the topic "Produits chimiques textiles – Recyclage":
Powar, Ajinkya. "ACV et éco-conception dans le domaine de l'élimination des produits chimiques des déchets textiles pour le recyclage des textiles." Electronic Thesis or Diss., Université de Lille (2018-2021), 2021. http://www.theses.fr/2021LILUN040.
The textile industry is evolving rapidly, and is also constantly changing. It is constantly developing new techniques for the recycling of the textiles and further research is vital for the future needs. The capability to recycle a textile material is a step towards a more green and sustainable industry. However, there are various challenges and difficulties associated with the recycling of textiles. Colorants and other impurities present on the textiles pose a big challenge to the continuity of the chemical recycling. The purpose of our study is to find out methods for the removal of the dyes or colorants from the cotton textiles for the end of life scenarios like recycling. The removal process of the chemical additives in an ecological way would add value to the recycling of textiles, which would help to obtain a recycled textile with the upgraded quality. To examine this subject, a literature study with respect to the chemicals and the removal process along with the recycling methods was done. In general, alkaline reductive treatment is performed using sodium hydroxide and reducing agent like sodium hydrosulphite for the color stripping of the reactive dyed textiles. Bibliographic survey on the various color stripping process, their drawbacks, viability for industrial scale-up etc was also performed. In this study, we have proposed the application of the ozone assisted process for the color stripping of the reactive dyed textiles using the pilot scale setup. The quality of the color stripped fabrics was determined in terms of the color stripping %, mechanical properties and the colorimetric analysis. Response surface methodology tools like the Box-Behnken design was utilized to examine the effects of three parameters like pH of the treatment (3-7), the reaction time (10-50 min) and the ozone concentration (5-85 g/m3 of ozone). With the ozonation process, color stripping of almost 98 % was achieved. The ozonation process is done at room temperature and also can be performed without any harsh chemicals. Additionally, we have also studied the other color stripping methods like the glucose based process. The results demonstrate that the glucose assisted process can emerge as an ecological alternative to the conventional process. Glucose can act as a green alternative reducing agent to the conventional reducing agent like sodium hydrosulphite. The damage to the mechanical properties are less as compared to the conventional and the ozone based process. However, the glucose assisted process utilized high temperatures for efficient color stripping. Finally, the study has highlighted the need of developing novel methods with minimum damage to the quality of the fibers. Amongst all the impact indicators, “Water resource depletion” is the highest for all the ozonation processes since it has the greatest relative value after normalization. It was found that the major contributors to the environmental impacts were Electricity and Oxygen formation. To optimize the impacts, new experimental conditions have been studied. Even, Color stripping of the pigment printed textiles was studied with the ozone assisted process. This study also highlights the need to study presence of contaminants like coatings present on the textiles during their end of life
Bao, Xulei. "L'impact de l'extraction sous vide avec recyclage sur l'application des solutions de produits chimiques aux nappes textiles." Mémoire, Université de Sherbrooke, 1990. http://savoirs.usherbrooke.ca/handle/11143/967.
Drevelle, Christophe Delobel René Duquesne Sophie Le Bras Michel. "Étude de la dégradation de films à base de résine acrylique utilisée dans l'industrie textile." [S.l.] : [s.n.], 2002. http://www.univ-lille1.fr/bustl-grisemine/pdf/memoires/F2002-153.pdf.
Sur la p. de titre : DEA-Structure et dynamique des systèmes réactifs, PERF-Procédés d'élaboration de revêtements fonctionnels. Bibliogr. f. : 21-22. Annexes.
Leclercq, Hervé. "Contribution à l'étude du comportement des colorants réactifs lors des traitements hydrothermiques post teinture." Mulhouse, 1987. http://www.theses.fr/1987MULH0041.
Convert, Reynald. "Contribution au développement d'un système expert pour la formulation des recettes de teinture." Mulhouse, 1998. http://www.theses.fr/1998MULH0525.
Lusinchi, Jean-Marie. "Optimisation des propriétés des mélanges de polyéthylène térephtalate avec les polyoléfines et le PVC." Montpellier 2, 1993. http://www.theses.fr/1993MON20192.
Grand, Julien. "Développement de nouveaux composés à l'iode hypervalent et leurs utilisations dans des réacions d'oxydation organocatalysées." Caen, 2013. http://www.theses.fr/2013CAEN2061.
Readily available hypervalent iodine compounds are considered as safe and environmentally friendly reagents for oxidative transformations. Since their discovery, more and more reagents and/or procedures have been developed and optimized affording efficient and economic hypervalent iodine chemistry protocols. Noticing those challenging research areas, this PhD work was orientated to encompass three actual topics of hypervalent iodine chemistry: (i) Straightforward synthesis of substituted dibenzofurans and novel fluorinated iododiarylethers were developped starting from substituted diaryliodolium salts (the cyclic variants of diaryliodonium salts). (ii) Various iodine containing cycloadducts were synthesized from the building block methyl 3-iodopropiolate and then evaluated as oxidative organocatalysts in oxidative transformations. (iii) The development of recyclable hypervalent iodine organo-catalysts was carried out by fixing iodine on nanometer-sized magnetically separable particles. These recyclable iodine containing nanoparticles were successfully evaluated as oxidative organocatalysts in oxidative transformations
Lalou, Ahmed. "Mise au point d'un procédé d'extraction des hémicelluloses à partir d'un substrat végétal ligno-cellulosique : application au cas des coques de tournesol." Toulouse, INPT, 1995. http://www.theses.fr/1995INPT028G.
Ezzahar, Samira. "Electro-extraction des cations en solution diluée par l'association de membranes et textiles échangeurs d'ions." Montpellier 2, 1996. http://www.theses.fr/1996MON20272.
Aubry, Carole. "Développement et mise en oeuvre de structures textiles multifonctionnelles contenant des nanotubes de carbone : application aux capteurs chimiques pour la détection de solvants." Thesis, Lille 1, 2009. http://www.theses.fr/2009LIL10153/document.
This work is performed through the European project Inteltex. The aim is to develop new textile structures for the solvent detection. The use of CPC (Conductive Polymer Composite) composed of an insulating polymer matrix and conductive fillers, allows to detect the solvent presence by the swelling of the polymer that induces the conductive network deconnexion and the decrease of the electrical conductivity. The use of carbon nanotubes (CNT) as conductive fillers is a biggest advantage because only a low content is necessary to achieve the appropriate electrical conductivity for sensing (10-3 S/m). The different sensitive and spinnable matrices are polycarbonate (PC), polylactide (PLA) and polyethylene terephthalate (PET). The percolation threshold of CNT in 1.5 mm diameter monofilament, produced by extrusion, is determined between 1.5 and 2 wt.% of CNT. The elaboration of multifilament yarns by melt spinning process show a decrease of the conductivity with the drawing effect. In order to maintain the electrical properties, PLA fibers containing at least 4 % of CNT and having a minimum diameter of 80 µm have to be produced. In this way it is necessary to introduce a plasticizer to improve the composites spinnability. The electrical, thermal, mechanical, morphological properties and fluidity of filaments were studied depending on the processing conditions and their composition. Composite fibers, close the percolation threshold, show sensitivity to humidity, ethanol and toluene
Books on the topic "Produits chimiques textiles – Recyclage":
Wang, Rui. Advances in Textile Engineering. Trans Tech Publications, Limited, 2011.
Jerold, M., A. Santhiagu, Rajulapati Sathish Babu, and Narasimhulu Korapatti. Sustainable Bioprocessing for a Clean and Green Environment: Concepts and Applications. Taylor & Francis Group, 2021.
Jerold, M., A. Santhiagu, Rajulapati Sathish Babu, and Narasimhulu Korapatti. Sustainable Bioprocessing for a Clean and Green Environment: Concepts and Applications. Taylor & Francis Group, 2021.
Jerold, M. Sustainable Bioprocessing for a Clean and Green Environment. Taylor & Francis Group, 2021.