654 resultados para Textiles.
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The main aim of this work is to understand the structureproperty-function relationship of the natural protective silkworm cocoon shells. This understanding will inspire further effort to tackle the perennial challenge of developing lightweight and highly protective textiles and composite structures. Such materials are essential for a wide range of applications including outdoor activities, healthcare, security, as well as defence sectors.
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Vascular implants have always been a key area of research in medical textiles. Knitted structures have been proven to be suitable for stent applications on the basis of their looped mesh geometry, structural flexibility and ease of manufacturing. However, there are biomechanical constraints of plain knit constructions that can result in clinical complications after implantation and hence cannot be ignored. This study reports a new segmented knit design inspired by structural metamerism observed in the body design of some invertebrate animals. Metamerism is the phenomenon of having a linear series of body segments fundamentally similar in structure, but assigned to perform different functions. It was hypothesized that utilization of this simple and yet effective biological design approach in stent construction could improve the degree of control for optimizing stent biomechanical properties. The proposed segmented stent was constructed by incorporating an elastic filament component into a polyethylene terephthalate knitted stent at specific intervals along its length, also known as the ‘Plating Technique’. This technique generates a structure with alternately arranged stiff and elastic knitted sections which equip the stent with vital structural support and volumetric compliance properties, respectively. The stent design parameters (filament diameter, loop length, segmentation plan) were optimized to achieve significantly better biomechanical performance (bending flexibility, compression resistance, volumetric expansion, longitudinal extensibility) than a plain knit stent.
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Fabrics with automatic one-way water transport ability are highly desirable for applications in daily life, industry, health, and defense. However, most of the studies on one-way water transport fabrics only report the qualitative water transport results. The lack of quantitative measure makes it hard to assess the directional transport quality. Here, it is proved that a hydrophilic fabric after being electrosprayed with a thin layer of hydrophobic coating on one side shows one-way water transport ability. By using moisture management tester, the water transport property is qualitatively characterized and the effect of hydrophobic fabric layer thickness on one-way water transport feature is examined. The hydrophobic fabric layer thickness is found to play a key role in deciding the one-way transport ability. When a plain woven fabric with an overall thickness of 420 μm and average pore size of 33 μm is used as fabric substrate, a hydrophobic fabric layer thickness between 22 and 62 μm allows the treated fabric to show a one-way droplet transport feature. A one-way transport index as high as 861 can be attained. The one-way water transport is durable enough to withstand repeated washing. This novel fabric may be useful for development of “smart” textiles for various applications.
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Silk fabrics were colored by gold nanoparticles (NPs) that were in situ synthesized through the induction of sunlight. Owing to the localized surface plasmon resonance (LSPR) of gold NPs, the treated silk fabrics presented vivid colors. The photo-induced synthesis of gold NPs was also realized on wet silk through adsorbing gold ions out of solution, which provides a water-saving coloration method for textiles. Besides, the patterning of silk was feasible using this simple sunlight-induced coloration approach. The key factors of coloration including gold ion concentration, pH value, and irradiation time were investigated. Moreover, it was demonstrated that either ultraviolet (UV) light or visible light could induce the generation of gold NPs on silk fabrics. The silk fabrics with gold NPs exhibited high light resistance including great UV-blocking property and excellent fastness to sunlight.
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Conducting polymer-coated textiles possess a wide range of electrical properties. The surface resistivity is influenced by concentrations of the reactants, the thickness of the coating, the nature of the substrate surface, the extent of penetration of the polymer into the textile structure, and the strength of the binding of the coating to the textile surface. Low resistivity in fabric results from highly doped thicker coatings that penetrate well into the textile structure, thus enabling good electrical contact between fibers. Microwave studies showed that conductive textiles are not highly effective as electromagnetic shielding materials owing to their medium-level conductivity and therefore large skin depth. Combined with the fact that coatings are around 1. ?m thick, they cannot act as effective reflective barriers to electromagnetic radiation. However, because they are highly absorptive in the microwave region, absorbing materials can be designed in conjunction with conductive textiles. Study of Fourier transform-infrared spectra of aged polypyrrole films has shown an increase in intensity of an ?,?-unsaturated conjugated carbonyl peak that may be linked to the increase in resistance but cannot be the only factor, because the rate of electrical decay was influenced by several factors such as temperature, the type and concentration of the dopant, and the aging time, all of which signify a complex mechanism of degradation of conductivity. Degradation is a major concern for conductive textile systems that needs to be characterized before considering these materials for potential applications.
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Developing soft actuators and sensors by means of 3D printing has become an exciting research area. Compared to conventional methods, 3D printing enables rapid prototyping, custom design, and single-step fabrication of actuators and sensors that have complex structure and high resolution. While 3D printed sensors have been widely reviewed in the literature, 3D printed actuators, on the other hand, have not been adequately reviewed thus far. This paper presents a comprehensive review of the existing 3D printed actuators. First, the common processes used in 3D printing of actuators are reviewed. Next, the existing mechanisms used for stimulating the printed actuators are described. In addition, the materials used to print the actuators are compared. Then, the applications of the printed actuators including soft-manipulation of tissues and organs in biomedicine and fragile agricultural products, regenerative design, smart valves, microfluidic systems, electromechanical switches, smart textiles, and minimally invasive surgical instruments are explained. After that, the reviewed 3D printed actuators are discussed in terms of their advantages and disadvantages considering power density, elasticity, strain, stress, operation voltage, weight, size, response time, controllability, and biocompatibility. Finally, the future directions of 3D printed actuators are discussed.
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Portugal’s manufacturing sector has a significant importance both in national income and employment. As has been pointed out by several researchers, the traditional methods of analysis fail to grasp all the dimensions of economic competitiveness. This dissertation is then, at its core, an analysis of Portugal’s manufacturing industry in terms of the latter’s value added to production and impact to employment under the framework of global value chains. The current dissertation seeks to study in which way the Portuguese manufacturing industry, and its respective sectors, has a direct and indirect impact on the creation of value added and employment and how this impact can be measured. For development of this work the input-output approach for calculation of multipliers and the new framework proposed by Timmer et al. (2013) for calculation of GVC income and GVC jobs indicators were used, elaborated on the basis of the WIOD project dataset. Moreover, to illustrate the application of the provided methodology the Portuguese textile industry was used as an example. It was found that the changes in final demand of such sectors as Pulp, Paper, Printing and Publishing; Machinery, Nec and Textiles and Textile Products would have a larger impact on generated value added than other manufacturing sectors. At the same time, employment created by the changes in final demand would be more impacted by such sectors as Food, Beverages and Tobacco; Wood and Products of Wood and Cork and Textiles and Textile Products. In this regard, the number of low-skilled workers in Portugal seems to be more effected by changes in final demand, than those occupied by higher -skilled individuals. Moreover, it was found that the distribution of GVC income and GVC jobs for the Portuguese manufacturing industry shares a similar outlook. However, upon closer inspection of GVC labour distribution by skill levels there seems to exist a general progression in which low-skilled jobs requirements are met by local resources, while the need for higher skilled jobs require a greater “off-shoring” of work The results obtained through calculations of presented multipliers provide a powerful tool for policy makers in strategic planning of development of national economy. Using the provided methodology and obtained results, a government and supranational organizations could define which industry would have the greatest impact for an additional unit of output generated through the economy, and thus define the sectors for further investments.
Disruptive Threads and Renegade Yarns: Domestic Textile Making in Selected Women's Writing 1811-1925
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Thesis (Ph.D, English) -- Queen's University, 2016-08-03 13:57:45.102
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32 documentos : ilustraciones, fotografías.
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Poly(ethylene terephthalate) (PET) fabric with highly and durable hydrophilic surface was fabricated using microwave-assisted glycolysis. Sodium hydroxide (NaOH) as a catalyst was proven to be suitable for PET glycolysis under assistance of microwave. The modified PET fabric (0.5% NaOH, irradiation 120 s) showed high surface hydrophilicity with a contact angle of 17.4 ° and a wicking length of 19.36 mm. The exposure of the carboxyl- and hydroxyl-end groups on the surface of PET and the introduction of etches were confirmed by Methylene Blue staining and field emission scanning electron microscopy (FESEM), receptively. Although the strength of PET fabric decreased after modification, it was still high enough for textile applications. The thermal properties of the modified PET fabrics were well maintained. The high hydrophilicity and its original properties of PET could be controlled by changing the irradiation time from 60 s to 120 s and adjusting the content of sodium hydroxide from 0.2% to 0.5%. These results suggest microwave-assisted glycolysis with sodium hydroxide is an effective method for PET hydrophilic finishing.
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This work has demonstrated a facile route to separate polyester/cotton blend textile waste by a chemical dissolution method. The recovered cellulose from textile waste were used to regenerate a novel composite fibre with improved properties which could potentially be used in textile applications.
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A silkworm cocoon is a biological porous structure which provides multiple protective functions. The knowledge from this natural protective system could contribute to develop advanced materials and structures with superior performances and meet the human demanding of novel breathable materials for enhanced thermal protection and comfort.
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Novel bifacial fabrics, with a woven structure on one face and a knitted structure on the other, were developed and produced on a purpose-built machine using conventional fibres. Bifacial fabrics have two breakages in warp and weft directions, and better thermal comfort properties than traditional woven and knitted fabrics.
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This project develops a novel photocatalyst for the cleaning of textile dyeing wastewater. The newly-developed photocatalyst was prepared by combing porous boron nitride nanosheets with titanium dioxide particles and these composites show potentials for the practical treatment of the textile dyeing wastewater in a large scale.
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La catalyse est à la base de la fabrication de médicaments, de produits textiles, d‘engrais, des pots d’échappement, et une multitude d’autres applications de notre quotidien. En effet, dans les pays industrialisés jusqu’à 80% des produits manufacturés utilisés au quotidien ont nécessité au moins une étape de catalyse lors de leur fabrication. Outre être actif, il est primordial pour un catalyseur performant d’être résistant à la désactivation qui se traduit par la perte d’activité ou de sélectivité d’un catalyseur au cours du temps. La synthèse d’un matériau multifonctionnel permet de répondre à ces différents critères. L’objectif d’un design intelligent de matériaux est de mener à des effets synergiques de chacune des composantes. Pour un catalyseur, en plus d’être actif et sélectif pour le produit désiré, il faut en plus qu’il soit durable, stable dans le temps, et permette d’être réutilisable. L’objectif de ce projet est de faire une synthèse originale, simple et reproductible d’un catalyseur actif et résistant à la désactivation. De base, un catalyseur se compose d’un support et d’un matériau actif. La nature, la morphologie et l’agencement de ces derniers dictent le comportement chimique du catalyseur final. Comme matériau actif, les nanoparticules d’or sont très prisées en raison de leur potentiel de catalyse élevée pour de nombreuses réactions. Cependant, aux températures de fonctionnement de la catalyse, les nanoparticules d’or ont tendance à se désactiver par coalescence. Pour remédier à cela, il est possible de déposer une couche de silice mésoporeuse afin de protéger les NPs d’or des rudes conditions de réaction tout en étant perméables aux espèces réactives. Plusieurs types de matériaux peuvent servir de support aux nanoparticules d’or. À ce titre, les particules d’oxydes de fer magnétiques telles que la magnétite (Fe[indice inférieur 3]O[indice inférieur 4]) sont intéressantes pour leur potentiel hyperthermique, phénomène par lequel des nanoparticules (NPs) magnétiques transforment de l’énergie électromagnétique provenant d’un champ externe haute fréquence en chaleur, créant ainsi des nano-fours. Une première couche de silice est utilisée comme matrice de greffage afin de fixer les nanoparticules d’or sur la magnétite. La structure visée est illustrée à la Figure ci-dessous. Figure 1 Structure du catalyseur de Fe2O4@SiO2-Au-SiO2m (Ge, Zhang, Zhang, & Yin, 2008) Plusieurs avenues d’assemblage et de synthèse sont explorées pour chacune des composantes de la structure visée. Les avantages et inconvénients ainsi que des mécanismes sont proposés pour chaque voie de synthèse. Le matériau est utilisé comme catalyseur pour la réaction de réduction du 4-Nitrophénol par du NaBH4. Pour ce qui est de la synthèse de magnétite par voie solvothermique, il a été démontré qu’il était important d’être dans un milieu sous pression puisque l’étape limitante de la réaction est la solubilité des particules de magnétites dans le milieu. Cela est en accord avec le principe de mûrissement d’Ostwald selon lequel les petites particules ont tendance à se dissoudre dans le milieu et précipiter à la surface des plus grosses particules de façon à diminuer l’énergie interfaciale. Cette synthèse a été reproduite avec succès et a mené à la production de nanoparticules de Fe[indice inférieur 3]O[indice inférieur 4] sphériques creuses d’une taille de 150 [plus ou moins] 30nm. Ces sphères creuses ont été recouvertes d’une couche de silice dense par une méthode de Stöber modifiée. Le recouvrement forme des amas de particules et est non uniforme en raison de la présence de poly(éthlyène glycol) à la sur face de la magnétite, un adjuvant présent lors de sa synthèse afin d’améliorer la dispersion de la magnétite. La synthèse et le greffage d’AuNPs sont bien maîtrisés : les AuNPs ont une taille de 17 [plus ou moins] 6nm et la quantité d’or greffé est assez élevée. Ultimement, une méthode de greffage alternative tel que le greffage par croissance in situ de nanoparticules d’or pourrait être emprunté afin d’obtenir des particules plus petites. Pour ce qui est de la formation d’une couche de silice mésoporeuse, la méthode par calcination est une meilleure option que par gravure chimique en raison de sa sélectivité envers la couche externe de silice plus élevée ainsi que la formation apparente de pores.
