Global ETD Search

51	Nanofiber Filter Media for Air Filtration Raghavan, Bharath Kumar 11 August 2010 (has links) No description available. Chemical Engineering Engineering Materials Science nanofibers mass production of nanofibers electrospinning ceramic nanofibers hot gas filtration air filtration filtration nanofiber filter media particle laoding on fibrous filter alumina nanofibers , nylon 6 nanofibers Nanopsider machine
52	EXPERIMENTAL DEVELOPMENT OF ADVANCED AIR FILTRATION MEDIA BASED ON ELECTROSPUN POLYMER FIBERS Ghochaghi, Negar 01 January 2014 (has links) Electrospinning is a process by which polymer fibers can be produced using an electrostatically driven fluid jet. Electrospun fibers can be produced at the micro- or nano-scale and are, therefore, very promising for air filtration applications. However, because electrospun fibers are electrically charged, it is difficult to control the morphology of filtration media. Fiber size, alignment and uniformity are very important factors that affect filter performance. The focus of this project is to understand the relationship between filter morphology and performance and to develop new methods to create filtration media with optimum morphology. This study is divided into three focus areas: unimodal and bimodal microscale fibrous media with aligned, orthogonal and random fiber orientations; unimodal and bimodal nanoscale fibers in random orientations; bimodal micrometer and nanometer fiber media with orthogonally aligned orientations. The results indicate that the most efficient filters, which are those with the highest ratio of particle collection efficiency divided by pressure drop, can be obtained through fabricating filters in orthogonal layers of aligned fibers with two different fiber diameters. Moreover, our results show that increasing the number of layers increases the performance of orthogonally layered fibers. Also, controlling fiber spacing in orthogonally layered micrometer fiber media can be an alternative way to study the filtration performance. Finally, such coatings presented throughout this research study can be designed and placed up-stream, down-stream, and/or in between conventional filters. Electrospinning Polymer Air Filtration Filters Morphology Nanofibers Nanoscience and Nanotechnology
53	Produção e caracterização de scaffolds de diferentes espessuras obtidos por eletrofiação de nanofibra polimérica e proteína. / Production and characterization of electrospun polymeric-protein nanofiber scaffolds with different thicknesses. Kimura, Vanessa Tiemi 26 September 2017 (has links) A engenharia tecidual visa repor, reparar ou ajudar a regenerar tecidos e órgãos danificados por meio da combinação de biomateriais, biomoléculas e células. Scaffolds de nanofibras biodegradáveis mimetizam a matriz extracelular natural fornecendo uma estrutura ideal para o crescimento celular. Blendas de policaprolactona (PCL) e gelatina são biodegradáveis e proporcionam uma combinação de boas propriedades mecânicas, do PCL, com a hidrofilicidade e caráter que promove a adesão celular, da gelatina. Neste contexto, o objetivo deste trabalho é avaliar a importância das diferentes espessuras de scaffolds eletrofiados em relação às suas propriedades principais. Quatro conjuntos de scaffolds de PCL/gelatina com diferentes espessuras foram produzidos sob as mesmas condições apenas aumentando o tempo de duração do processo de eletrofiação. Os resultados indicam que as espessuras aumentaram proporcionalmente ao tempo de eletrofiação, variando de 100 nm a 300 nm nos períodos de 1 a 3 horas, enquanto a densidade aparente e a porosidade mantiveram-se constantes. As micrografias das membranas revelaram fibras lisas com diâmetros maiores para os scaffolds de menor espessura, e fibras irregulares com diâmetros menores e regiões fundidas ou ligadas para os scaffolds de maior espessura. Além disso, o aumento da espessura melhorou a resistência mecânica e a molhabilidade dos scaffolds. A esterilização por peróxido de hidrogênio não modificou quimicamente a composição das membranas de PCL/gelatina, embora algumas amostras tenham se deformado. As membranas também apresentaram bons resultados de citotoxicidade, melhorando a viabilidade celular, apesar desses valores diminuírem minimamente para os scaffolds de maior espessura, provavelmente devido à maior quantidade de PCL. O teste de adesão não foi conclusivo e deverá ser repetido. / Tissue engineering aims to replace, repair, or helping regenerate damaged tissues and organs through the combination of biomaterials, biomolecules and cells. Biodegradable nanofibrous scaffolds mimic the natural extracellular matrix providing an ideal structure to cellular growth. Blends of polycaprolactone (PCL) and gelatin are biodegradable and provide a combination of good mechanical properties, from PCL, with the hydrophilicity and cell adhesion promoter character, from gelatin. The aim of this work was to evaluate the importance of the thickness of electrospun scaffolds on their key properties. Four sets of PCL/gelatin scaffolds with different thicknesses were produced under the same conditions by simply increasing the time length of electrospinning process. Results indicate that the thickness increases proportionally to the electrospinning time, varying from 100 nm to 300 nm in periods of 1 to 3 hours, while the apparent density and porosity remained constant. Micrographs from the nonwoven mats revealed smooth fibers with larger diameters in the thinner scaffold, and irregular fibers with smaller diameters and molten or bonded regions as the thickness increased. Furthermore, the increase of thickness improved mechanical resistance and wettability of the scaffolds. Plasma sterilization did not modify chemical composition of PCL/gelatin membranes, although some samples have been deformed. Membranes also presented good results for cytotoxicity, improving cell viability, despite these values decreased minimally to the thicker scaffolds, probably due to the higher amount of PCL. Adhesion test was not conclusive and might be repeat. Biomaterials Electrospinning Engenharia tecidual Materiais nanoestruturados Nanofibers Scaffold Tissue engineering
54	Optical Transparent Pmma Composite Reinforced By Coaxial Electrospun Pan Hollow Nanofibers Antoine, Donley 05 1900 (has links) Electrospinning has been recognized as an efficient technique for the fabrication of polymer fibers. These electrospun fibers have many applications across a broad range of industries. In this research, optical transparent composites were successfully fabricated by embedding polyacrylonitrile (PAN) hollow nanofibers into poly (methyl methacrylate) (PMMA) matrix. The hollow PAN nanofibers were prepared by coaxial electrospinning. The PAN was used as the shell solution, and the mineral oil was used as the core solution. The resulting fibers were then etched with octane to remove the mineral oil from the core. The hollow PAN fibers were then homogeneously distributed in PMMA resins to fabricate the composite. The morphology, transmittance and mechanical properties of the PAN/PMMA composite were then characterized with an ESEM, TEM, tensile testing machine, UV-vis spectrometer and KD2 Pro Decagon device. The results indicated that the hollow nanofibers have relatively uniform size with one-dimensional texture at the walls. The embedded PAN hollow nanofibers significantly enhanced the tensile stress and the Young's modulus of the composite (increased by 58.3% and 50.4%, respectively), while having little influence on the light transmittance of the composite. The KD2 Pro device indicated that the thermal conductivity of the PMMA was marginally greater than the PAN/PMMA composite by 2%. This novel transparent composite could be used for transparent armor protection, window panes in vehicles and buildings, and airplane windshield etc. PMMA PAN nanofibers composite material light transmittance PAN/PMMA
55	Augmentation de la limite élastique des composites à matrice céramique : SiC/SiC ou SiC/MAC Abchiche, Bruno 25 November 2013 (has links) Les matériaux composites connaissent un large succès. En effet les Composites à Matrice Céramique (CMC) fonctionnant à haute température ont des performances inégalées en termes de fatigue thermomécanique. La durée de vie des CMC est pourtant limitée en raison de l'apparition précoce de fissures matricielles, ouvrant autant de portes à des environnements agressifs, entraînant un abattement prématuré des propriétés mécaniques. Arriver à retarder la fissuration matricielle devient donc une étape clé pour une future importante utilisation des CMC dans l'aéronautique ou l'aérospatial. Les travaux de cette thèse se sont inscrits dans cette logique, où pour protéger les fibres et l'interphase de l'oxydation et de la corrosion, les propriétés de la matrice céramique ont tenté d'être modifiées par l'incorporation de nanofibres en leur sein et par l'émoussement de leurs macropores résiduels. / Abstract CMC PIP réactive SiC Nanofibres CMC PIP reactive SiC Nanofibers
56	Exergetic Life Cycle Assessment of Electrospun Polyvinylidene Fluoride Nanofibers Abbasi, Salman Ali 29 October 2014 (has links) Assessing the sustainability of nanomanufacturing products and processes has been difficult to achieve using conventional approaches mainly due to an inadequate inventory, large process-to-process variation, and a dearth of relevant toxicology data for nanomaterials. Since these issues are long term in nature, it is required to create hybrid methodologies that can work towards filling the existing gaps. Merging thermodynamic techniques such as the exergy analysis with environmental assessments can help make better, more informed choices while providing an opportunity for process improvement by enabling to correctly quantify efficiency loss through the waste stream, and by locating the exact areas for improvement. A preliminary technique that utilizes environmental assessment feedback during the process design along with an exergy analysis is presented. As a test case, an environmental assessment aided by an exergy analysis was carried out on the electrospinning process for producing polyvinylidene fluoride nanofibers. The areas of greatest concern, both from an environmental as well as a thermodynamic point of view, have been found to be the high energy consumption and the complete loss of solvent during the process of electrospinning. Interestingly, exergy consumption is significantly higher for fibers with a smaller ( Electrospinning Exergy LCA Nanofibers PVDF Sustainability Mechanical Engineering
57	Nanocarbon/polymer brush materials synthesis, characterization and application / Li, Lang, January 2007 (has links) Thesis (Ph. D. in Chemistry)--Vanderbilt University, Dec. 2007. / Title from title screen. Includes bibliographical references.
58	Carbon nanotube and nanofiber reinforcement for improving the flexural strength and fracture toughness of portland cement paste Tyson, Bryan Michael 2010 May 1900 (has links) The focus of the proposed research will be on exploring the use of nanotechnology-based nano-filaments, such as carbon nanotubes (CNTs) and nanofibers (CNFs), as reinforcement in improving the mechanical properties of portland cement paste as a construction material. Due to their ultra-high strength and very high aspect ratios, CNTs and CNFs have been used as excellent reinforcements in enhancing the physical and mechanical properties of polymer, metallic, and ceramic composites. Very little attention has been devoted on exploring the use of nano-filaments in the transportation industry. Therefore, this study aims to bridge the gap between nano-filaments and transportation materials. This will be achieved by testing the integration of CNTs and CNFs in ordinary portland cement paste through state-of-the-art techniques. Different mixes in fixed proportions (e.g. water-to-cement ratio, air content, admixtures) along with varying concentrations of CNTs or CNFs will be prepared. Different techniques commonly used for other materials (like polymers) will be used in achieving uniform dispersion of nano-filaments in the cement paste matrix and strong nano-filaments/cement bonding. Small-scale specimens will be prepared for mechanical testing in order to measure the modified mechanical properties as a function of nano-filaments concentration, type, and distribution. With 0.1 percent CNFs, the ultimate strain capacity increased by 142 percent, the flexural strength increased by 79 percent, and the fracture toughness increased by 242 percent. Furthermore, a scanning electron microscope (SEM) is used to discern the difference between crack bridging and fiber pullout. Test results show that the strength, ductility, and fracture toughness can be improved with the addition of low concentrations of either CNTs or CNFs. Carbon nanotubes Carbon nanofibers cement dispersion bond strength ductility
59	Advanced Fibrous Scaffold Engineering for Controlled Delivery and Regenerative Medicine Applications Liao, I-Chien January 2010 (has links) <p>Continuous nanostructures, such as electrospun nanofibers, embedded with proteins may synergistically present the topographical and biochemical signals to cells for tissue engineering applications. In this dissertation, co-axial electrospinning is introduced as a mean to efficiently encapsulate and release protein and live entities while producing a tissue engineering scaffold with uniaxial topography. In the first specific aim, aligned poly (caprolactone) nanofibers encapsulated with BSA and growth factors were produced to demonstrate controlled release and bioactivity retention properties. Control over release kinetics is achieved by incorporation of poly(ethylene glycol) as a porogen in the shell of the fibers. PEG leaches out in a concentration and molecular weight dependent fashion, leading to BSA release half-lives that range from 1 -20 days. The second specific aim introduces the fabrication of virus and bacterial cell encapsulated electrospun fibers to achieve unique biological functionalization. Adenovirus encoding the gene for green fluorescent protein was efficiently encapsulated into the core of poly(caprolactone) fibers through co-axial electrospinning and subsequently released via the porogen-mediated process. Encapsulated bacterial cells were confined to fibers of varying core sizes, which provided an aqueous core environment for free mobility and allowed the bacterias to proliferate within the fibers. </p><p>In the third specific aim, the differentiation of skeletal myoblasts on aligned electrospun polyurethane fibers and in the presence of electromechanical stimulation were systematically studied. Skeletal myoblasts cultured on aligned polyurethane (PU) fibers showed more pronounced elongation, better alignment, upregulation of contractile proteins and higher percentage of striated myotubes compared to those cultured on random PU fibers and film. In the last specific aim, the controlled release aspect of co-axial electrospun fibers were combined with skeletal tissue engineering to serve as a therapeutic implant for the treatment of hemophilia. A non-viral, tissue engineering approach were taken to stimulate local lymphatic or vascular system in order to enhance transport near the FVIII-producing implants to provide effective and sustained treatment for hemophilia A. Stable FVIII-producing clones were engineered from isolated myoblasts and cultured on aligned, protein-releasing electrospun fibers to form skeletal myotubes. The implanted construct rapidly integrated with host tissue and selectively induced angiogenesis or lymphangiogenesis as a result of the encapsulated growth factors. Constructs inducing angiogenesis significantly enhanced the transport of produced FVIII and achieved hemophilia phenotypic correction over two months. The use of co-axial electrospun fibers to serve as controlled delivery and tissue engineering construct furthers the continued pursue of a more sophisticated and medically relevant implant scaffold design.</p> / Dissertation Engineering, Biomedical Electrospinning Nanofibers Skeletal muscle Tissue Engineering
60	Electro-spun PAN-Based Activated Carbon Nanofibers as Electrode Materials for Electric Double Layer Capacitors Wu, Kuan-chung 27 July 2012 (has links) Uniform and aligned nanofibers have been obtained by eletrospinning. Activated carbon nanofibers (ACNFs) have been used as electrode materials for battery and electric double layer due to its porous properties. A high value of surface area can be attained (1000 - 3000 nm) by activation, due to the presence of micropores on the surface of nanofibers. A series of nanofibers have been prepared using different polymer precursors and concentrations by electrospinning in this study. Morphological study by SEM reveals a uniform and aligned fibrous structure for the PAN-based CNF (11 wt%) and a curved and twisted fibrous structure for the PAN-based CNF (8 wt%) and the acrylic-based CNF (9 wt%). Thus, the microstructure of CNF can be greatly influenced by the concentration of polymer precursor; high quality of nanofibers can be produced with higher polymer concentration and higher viscosity. The diameter of PAN-based nanofibers is gradually decreased from 400 to 200 nm during stabilization, carbonization, and activation, due mainly to the degradation and condensation. Surface of CNF becomes rough after activation due to the etching by potassium ions at high temperatures. Microstructural study by X-ray diffraction and Raman spectroscopy indicates a discernible diffraction peak at d002 = 0.356 nm and the ratio ID/IG = 1.83 of ACNFs, showing an amorphous and disordered structure, and leading to a low conductivity. Adsorption/desorption isotherms obtained from BET measurements under nitrogen atmosphere suggests a relatively small surface area of 8-10 m2/g, indicating that there might be no adsorption on the porous ACNF or the porous structure has been destroyed after carbonization. This leads to a relatively low conductance of 17 Faraday/g measured from the cyclic voltammetry. Raman spectroscopy microstructure activated carbon nanofibers electrospinning supercapacitors

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