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Academic literature on the topic 'Filage en voie fondue bicomposant'
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Dissertations / Theses on the topic "Filage en voie fondue bicomposant"
Kaleem, ullah Hafiz Muhammad. "Développement de fibres bicomposantes innovantes pour le textile de confort thermique." Electronic Thesis or Diss., Centrale Lille Institut, 2022. http://www.theses.fr/2022CLIL0034.
Full textThis study is part of Interreg European Project between Haute de France and Belgium. The project is called Photonitex. The aim of this project is to develop a personal thermal regulation intelligent textile that dynamically controls skin temperature. This work was done in collaboration between Centre Européen des Textiles Innovants (CETI) and School National Superior of Textile Arts and Industries (ENSAIT).The objective of this thesis is to develop a bicomponent fibers for thermal comfort textile. The literature review was done to select the most suitable polymer materials that are commonly used in textile industry. In addition, based on the literature review, the design of the trilobal bicomponent fibers was finalized to realize the dynamic thermal comfort textile. Moreover, used polymer materials must exhibit hydrophilic difference to achieve the dynamic thermal properties in fabrics. The inner material of this bicomponent trilobal fiber must be more hydrophilic than the outer material. PA6 and PA6-6 were selected as hydrophilic core and PET hydrophobic outer material for trilobal bicomponent filaments. However, PA6 and PA6-6 are incompatible and immiscible to PET. The major challenge to achieve the desired bicomponent fibers is to acquire a sufficient adhesion at the interface to avoid the pre-splitting or separation between these two polymer materials. In order to improve their miscibility at the interface PA12 was added in PA6 and PA6-6 at 5, 10, 15% wt % via polymer compounding process. In order to produce trilobal bicomponent filament via coextrusion melt spinning process, rheological behavior of the used polymer materials play an important role. To select the most suitable materials for trilobal bicomponent fiber, rheological studies were conducted on pure and polymer blends using capillary rheometer. In addition, hydrophilic properties of each polymer and their blends were also tested on knitted fabrics with contact angle and wicking measurements. To evaluate the effect of PA12 on PET and PA6 interfacial adhesion, bicomponent PET/PA6 sheath/core fibers were produced via melt spinning process and interfacial adhesion was investigated through techniques (tensile test, dynamic mechanical thermal analysis (DMTA), Wide Angle Xray Diffraction (WAXD), Differential scanning calorimetry (DSC), and Scanning Electron Microscope (SEM)). Based on the obtained results from the above mentioned techniques, the most suitable composition was produced in trilobal bicomponent fibers for thermal comfort fabrics. Simulation studies were also performed using Compuplast 3D FEM software to optimize the melt spinning process settings and produce trilobal bicomponent fibers.The textile made out of such innovative bicomponent fibers will show a self-actuation phenomenon are autonomous, self-empowered, and adaptive to the environment. This will help to mitigate the higher energy consumptions by conventional indoor heating, cooling, and ventilation systems and eventually minimizes the global energy consumptions and climate issues
Bouchard, Jonas. "Développement de nouvelles fibres thermostables fonctionnelles chargées en nanotubes de carbone pour des matériaux composites structuraux dans des applications aéronautiques et ferroviaires." Thesis, Lille 1, 2013. http://www.theses.fr/2013LIL10052/document.
Full textThis study falls within the framework of the European project IMS&CPS (Innovative Material Synergies & Composite Processing Strategies) and aims at developing new carbon-nanotubes-based thermostable polyethersulfone (PES) fibres. The main goal of this project is the alignment, orientation and integration of carbon nanotubes (CNT) in structural composite materials in order to obtain improved mechanical, thermal and electrical properties, for shielding against electromagnetic interference (EMI) and protection against lightning strike. Using CNT as conductive fillers allows the improvement of electrical conduction inside the fibres and then in the composites by the fibres’ dissolution and the CNT migration in the epoxy composite matrix. A first part focuses on the conductibility and the fire behaviour of the nanocomposites PES/CNT. In a second part, melt and wet spinning were studied as methods for producing nanocomposite fibres. To process PES/CNT by melt spinning it was necessary to add a plasticizer and adapt the heating panels, and this allowed PES melt-spun fibres containing up to 1.5 wt. % CNT to be obtained. CNT pre-orientation and alignment in the production axis of the fibres was also noticed. Then, a weaving process permitted CNT orientation in different directions. Using the wet spinning process, a higher CNT content (2 wt. %) was incorporated in the PES fibres. An electrical percolation threshold of around 1 wt. % CNT incorporated in the PES wet-spun fibres was reached. In both spinning methods, a correlation between processing, morphologies, mechanical and electrical properties of the elaborated fibres was established. The evolution of the fibres’ morphologies and electrical properties after their dissolution in epoxy resins is also mentioned and reveals a significant improvement of their electrical conductivity in the composite matrix
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.
Full textThis 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
Yan, Xiang. "Design of biphasic polymeric fiber from melt-spinning charged with nanoparticles : effects of the formulation and the fillers localization, to obtain a functionalized fiber at surface level." Thesis, Lille 1, 2019. http://www.theses.fr/2019LIL1I084.
Full textThe work aims to make the functional porous polypropylene (PP) fibers as well as PP microfibers, by the melt spinning of PP-poly(vinyl alcohol) (PVA) blends followed with the selective phase extraction of PVA. The objective is to first find out the optimal ratio of PP and PVA for fabrication of multifilament yarns by melt spinning, and to localize the filler at the biphasic interface. The fillers include not only the homogenously modified silica nanoparticles, but also the kaolinite Janus particles. The concomitant morphology evolution of the extrudates and fibers were observed. The work mainly discusses about the fabrication of porous fibers, but also makes an exploratory experiment to reverse the ratio to fabricate the microfibers. It was found that the ratio of two polymers as 70 wt.%/30 wt.% is an ideal formula for fabricating the porous fibers. Both of the two fillers are successfully tailored at the biphasic interface. The localization of silica nanoparticles within the biphasic can be fixed by the thermodynamic control, and one of the sorts has been dominantly localized at the biphasic interface. In addition, the Janus particles provide an alternative way to have the interface localization, which even helps the mechanical enhancement. The feasibility of microfiber production with the embedment of the fillers was also demonstrated
Rault, François. "Mise en oeuvre et propriétés mécaniques, thermiques et de tenue au feu de filaments à base de polypropylène chargé en nanoparticules." Valenciennes, 2008. http://ged.univ-valenciennes.fr/nuxeo/site/esupversions/fdf2aa0d-1453-4fee-8b94-d1e493d57372.
Full textThe french textile industry meets stiff competition. The firms try to differentiate themselves by improving or adding new properties to their products. The cost remaining a major concern, PP, polymer with an interesting compromise cost / ownership, is therefore widely used. Different ways exist to functionalize this polymer. One of them is to add fillers. However, the size and rate of particles commonly added to achieve satisfactory properties cause difficulties during the melt spinning process. Due to their characteristics (size and filler rate), nanoparticles offer an interesting alternative to explore. Blends PP / Clay were prepared with a twin-screw extruder before being spun. A strong decrease in the elongation properties of filaments in the presence of clay, probably due to its low exfoliation, brings us to consider the preparation of ternary blends (PP / PA-6 / Clay). However, it was not possible to spin these blends for a filler rate higher than 1 wt% due to their specific morphologies. Filaments of PP filled with clay and graphite and filaments of PP filled with based manganese nanoparticles have also been produced to assess their mechanical and thermal properties. Under air, thermal stability of PP has been improved with all tested fillers. And finally, the filaments made were used to produce knitted fabrics, whose fire properties have been studied with a cone calorimeter
Grillard, Fabienne. "Structure et propriétés de fibres composites polymère-nanotubes de carbone obtenues par voie fondu." Thesis, Bordeaux 1, 2012. http://www.theses.fr/2012BOR14577/document.
Full textThis thesis reports the study of the properties and structure of carbon nanotube / polymercomposite fibers obtained by melt spinning. By contrast to most fibers produced by thistechnology, the fibers produced in this thesis are electrically conductive. The conductivityproperties are studied as a function of various parameters including temperature andmechanical stress. It is shown that fiber drawing induced by the process leads to a relativetranslation of the nanotubes relative to each other and to a loss of electrical contacts. Ananalytical model accounts for this phenomenon and reproduces the experimental results.Polymer-nanotube fibers exhibit also particularly original thermomechanical properties suchas shape memory effects that are controllable by the programming process. Surprisingly, thefibers have a temperature memory reflected by a peak of the generated stress at thetemperature at which the materials has been programmed. These effects have beendemonstrated for various types of deformations including elongation and torsion. Althoughthese effects are governed by the properties of the polymer, it is shown that the introductionof nanotubes provides significant improvements of the thermomechanical properties
Kechiche, Mohamed Bouraoui. "Etude et développement de capteurs / effecteurs filamentaires de faibles diamètres intégrables dans des structures textiles." Phd thesis, Université de Haute Alsace - Mulhouse, 2012. http://tel.archives-ouvertes.fr/tel-00844135.
Full textVandesteen, Marie. "Synthèse et modification d'un polyester biodégradable pour application agro-textile : le poly(butylène succinate)." Thesis, Lyon, INSA, 2015. http://www.theses.fr/2015ISAL0022.
Full textIn the last decade, biodegradable polymers have gained significant interest for agricultural applications. Here we focus on the development of biodegradable textiles for insect-proof nets. Currently these textiles must be collected by specialized companies after the growing season and generate disposal cost. An ideal agrotextile would be collected by the user at the end of the growing season, and undergo full mineralization within few months. These requirements can be achieved by using biodegradable polymers. In this study, poly(butylene succinate) (PBS), a biobased and biodegradable polymer was studied. PBS was synthesized by polycondensation on a pilot plant reactor. Because of low rheological properties of the synthesized polyester, the chemical structure of PBS was modified by several approaches like chain extension or branching. The mechanical properties were tuned with the synthesis of PBS/PLA transreacted systems and PBS nanocomposites. These modified PBS were tested upon fiber spinning. Finally a PBS yarn with 0,5% spherical silica was produced at higher scale and a textile was done. Ageing of the PBS yarns was also studied and the conservation of the mechanical properties during use of the textile was validated. Lastly a more exploratory approach was tested. It is synthesis of modified PBS by supramolecular interactions, which are reversible upon temperature