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61	Microfibrillated cellulose: Energy-efficient preparation techniques and applications in paper Ankerfors, Mikael January 2015 (has links) This work describes three alternative processes for producing microfibrillated cellulose (MFC; also referred to as cellulose nanofibrils, CNF) in which bleached pulp fibres are first pretreated and then homogenized using a high-pressure homogenizer. In one process, fibre cell wall delamination was facilitated by a combined enzymatic and mechanical pretreatment. In the two other processes, cell wall delamination was facilitated by pretreatments that introduced anionically charged groups into the fibre wall, by means of either a carboxymethylation reaction or irreversibly attaching carboxymethylcellulose (CMC) to the fibres. All three processes are industrially feasible and enable energy-efficient production of MFC. Using these processes, MFC can be produced with an energy consumption of 500–2300 kWh/tonne. These materials have been characterized in various ways and it has been demonstrated that the produced MFCs are approximately 5–30 nm wide and up to several microns long. The MFCs were also evaluated in a number of applications in paper. The carboxymethylated MFC was used to prepare strong free-standing barrier films and to coat wood-containing papers to improve the surface strength and reduce the linting propensity of the papers. MFC, produced with an enzymatic pretreatment, was also produced at pilot scale and was studied in a pilot-scale paper making trial as a strength agent added at the wet-end for highly filled papers. / <p>QC 20150126</p> Microfibrillated cellulose microfibrillar cellulose nanofibrillated cellulose nanofibrillar cellulose cellulose nanofibrils nanocellulose MFC NFC CNF production techniques energy efficient gel properties films enzymes carboxymethylation carboxymethyl cellulose CMC mechanical properties oxygen barrier homogenization linting papermaking
62	Contribution à la valorisation electrique des piles à combustible microbiennes / Contribution to electrical valorization of microbial fuel cells Khaled, Firas 21 January 2016 (has links) Les Piles à Combustible Microbiennes (PCMs) produisent de l’électricité à partir de la dégradation de matières organiques par des bactéries. Les PCMs sont considérées comme des micro- génératrices à faible tension et faible puissance. Dans le but de récupérer l’énergie électrique produite afin de pouvoir alimenter des capteurs autonomes, des architectures mettant en œuvre plusieurs piles seront préférées. L'association d'un grand nombre de PCMs individuelles offre des perspectives très intéressantes notamment au niveau de la production d'énergie électrique. Cela permet d’atteindre des niveaux de tension acceptables en sortie et permet de mutualiser les puissances électriques de chaque cellule. L’association série d’un grand nombre de PCMs est un défi en soi à cause des couplages hydrauliques (lorsque les PCMs partagent le même substrat) et à cause des non-uniformités entre générateurs qui mènent à une association non-efficace. Les circuits d'équilibrage de tension peuvent être une solution pour compenser ces inhomogénéités. Ils peuvent améliorer l’efficacité de l’association et prévenir le phénomène d'inversion de tension. L’association hydraulique des biopiles permet d’éviter la chute de puissance liée au manque de carburant. Une fuite de charge entre les PCMs va diminuer le rendement global de l’association. Le débit du flux doit être contrôlé pour éliminer ce problème. Un flux de la cathode vers l’anode provoque des pertes supplémentaires dues à la fuite d’oxygène. La récupération d’énergie à partir de PCMs nécessite une unité de gestion d’énergie qui adapte la tension et contrôle le fonctionnement de la PCM. Un convertisseur flyback à faible tension d’entrée, autonome et auto-démarrant a été conçu et optimisé pour la récupération d’énergie à partir des PCMs. La récupération d’énergie à partir des PCMs peut être présentée comme une source alternative pour éliminer les batteries dans les applications de faible puissance (capteur autonome). / Microbial Fuel Cells (MFCs) are bioreactors that convert chemical energy in organic compounds to electrical energy through the metabolism of microorganisms. Organic matters are widely available in the environment that contains a huge amount of energy. This energy could be harvested, converted, by the technology of MFCs, to be used in certain applications. Energy production of a MFC is limited in low voltage value and low-power values what limits the potential applications. To step-up the voltage of MFCs to be suitable for real applications, an efficient power management unit (PMU) is required with a specific design to deal with their characteristics. A flyback converter under discontinuous conduction mode (DCM) is the most adapted to such low-power source like MFCs, offers a simple implementation, and low losses conversion system. The flyback converter has a good efficiency that can reach 75% with one MFC and about 80% when it is supplied by a serial stack of MFCs. Associations of MFCs are very interesting to increase the output power and expand the domain of application. Parallel association is a method to increase the output current but it imposes limitations in conversion efficiency due to the low output voltage of the stack. Contrarily, the serial association steps-up the voltage what leads to better performance of the converter. However the non-uniformities between cells in a serial stack affect negatively the performance of the stack. Voltage balancing circuits are considered as the solution to compensate this phenomenon. In the switched-capacitor method, an external capacitor is used to transfer the energy from the strongest MFC(s) to the weakest one(s). The losses in the switched-capacitor circuit are less than the losses of the switched-MFCs. The switched-capacitor offers an efficient, simple, low consumption method to optimize the performance and prevent the voltage reversal of the weak cells. Integration of this circuit can optimize the efficiency. Continuous operation mode by hydraulically connection between MFCs can continuously refresh the substrate to give an autonomous energy harvesting system. On the other hand, in some applications, e.g. a wastewater treatment plant, MFCs could not be hydraulically isolated. In this configuration, a leakage charge between the associated MFCs will decrease the global efficiency. The flow rate has to be controlled to eliminate this problem. A flow from cathodes to anodes causes additional losses due to the oxygen leakage. A temperature sensor is continuously supplied by alternatively connecting two MFCs. Each MFC supplies the sensor for two days. The flyback converter is able to continuously supply the sensor from the energy harvested from one continuously-fed MFC. This could be a good example, in a wastewater treatment plant (WWTP), to supply monitoring systems or also to supply low power applications of a building from a local WWTP. Electrotechnique Pile à combustible Pile à combustible microbienne Récupération d'énergie Gestion de l'énergie Energie renouvelable Electrotechnics Fuel cell Microbial full cell - MFC Energy haversting Power management DC/DC converter Low-Power applications Renewable enegry 621.313 072
63	Microfibrillated cellulose : Energy-efficient preparation techniques and key properties Ankerfors, Mikael January 2012 (has links) This work describes three alternative processes for producing microfibrillated cellulose (MFC) in which pulp fibres are first pre-treated and then homogenized using a high-pressure homogenizer. In one process, fibre cell wall delamination was facilitated with a combined enzymatic and mechanical pre-treatment. In the two other processes, cell wall delamination was facilitated by pre-treatments that introduced anionically charged groups into the fibre wall, by means of either a carboxymethylation reaction or irreversibly attaching carboxymethyl cellulose (CMC) onto the fibres. All three processes are industrially feasible and enable production with low energy consumption. Using these methods, MFC can be produced with an energy consumption of 500–2300 kWh/tonne, which corresponds to a 91–98% reduction in energy consumption from that presented in earlier studies. These materials have been characterized in various ways and it has been demonstrated that the produced MFCs are approximately 5–30 nm wide and up to several microns long. / <p>QC 20120928</p> Microfibrillated cellulose microfibrillar cellulose nanocellulose MFC NFC production techniques energy efficient gel properties films enzymes carboxymethylation carboxymethyl cellulose CMC mechanical properties oxygen barrier homogenization Paper, Pulp and Fiber Technology Pappers-, massa- och fiberteknik
64	Novel nanostructured ternary metal oxide composite for sequestration of trace metals from simulated aqueous solutions. Kupeta, Albert Jerry Kafushe 06 1900 (has links) D. Tech. (Department of Chemistry, Faculty of Applied and Computer Sciences), Vaal University of Technology / A novel low-cost ternary Mn-Fe-Cu (MFC) metal oxide nanocomposite adsorbent was fabricated using facile co-precipitation method and successfully applied for the sequestration of Cr(VI) and As(III) from simulated aqueous efflent. The central composite design (CCD) of the response surface methodology (RSM) optimization technique determined the optimal working parameters for the preparation of the ternary MFC metal oxide nanocomposite. The spectroscopic microstructural analysis of the ternary MFC metal oxide nanocomposite was performed using fourier transform infrared (FTIR) spectroscopy, transmission electron microscopy (TEM), scanning electron microscopy (SEM), X-ray photoelectron spectroscopy (XPS) and X-ray diffraction (XRD) spectroscopy. The spectroscopic analyses revealed a rough surface with hydroxyl groups and the presence of mixed metal oxides in different valence states. The BET surface area, pore volume and pore size of the nanostructured MFC ternary metal oxide composite were found to be 77.2427 m2/g, 0.2409 cm3/g and 14.7560 nm, respectively. The pH drift method determined that the pHpzc of the adsorbent was 6.75. The batch technique was employed to investigate the adsorption dynamics (effects of ionic strength, co-existing anions, adsorbent regeneration and reuse) and optimum parameters (solution pH, adsorbent dosage concentration, desorption) of Cr(VI) and As(III) adsorption onto the MFC nanocomposite. The fitting of non-linear kinetic (pseudo-first-order, pseudo-second-order and Elovich), diffusion (intraparticle and Boyd) and isotherm (Langmuir, Freundlich and Dubinin-Radushkevich) models to the Cr(VI) and As(III) experimental adsorption data gave an insight into the adsorption mechanisms. The Langmuir adsorption capacities, qm (mg/g), were 168.71 at solution pH 3 and 35.07 at solution pH 9 for Cr(VI) and As(III) adsorption, respectively. The adsorption of Cr(VI) onto the ternary MFC metal oxide nanocomposite was physical and formed outer-sphere surface complexes through electrostatic interactions, while the removal of As(III) was specific due to inner-sphere surface complexation and ligand/ion exchange reactions. The results from XPS and FTIR analysis after the adsorption of Cr(VI) and As(III) showed that the surface hydroxyl groups on the MFC nanocomposite interacted with the Cr(VI) and As(III) species during the formation of the surface complexes. To facilitate ease of adsorbent removal from the treated simulated aqueous effluent, the ternary MFC metal oxide system was co-precipitated onto biochar support. Aqueous solutions Trace Metals Metal oxide composite Ternary nanocomposite Central composite design Response surface methodology Mn-Fe-Cu (MFC) Transmission electron microscopy Dissertations, Academic -- South Africa Nanostructured materials Nanocomposites (Materials)
65	Study on the effects of matrix properties on the mechanical properties of carbon fiber reinforced plastic composites / 炭素繊維強化複合材料の機械特性に及ぼす母材特性の影響に関する研究 / タンソセンイキョウカフクゴウザイリョウノキカイトクセイニオヨボスボザイトクセイノエイキョウニカンスルケンキュウ邵永正, Yongzheng Shao 22 March 2015 (has links) It was found that a significant improvement of mechanical properties of CFRPs can be achieved by the adjustment of the matrix properties such as toughness and CF/matrix adhesion via the chemical modification, as well as the physical modification by a small amount of cheap and environment-friendly nano fibers. Based on investigation of fracture mechanisms at macro/micro scale, the effects of matrix properties and nano fiber on the mechanical properties of CFRP have been discussed. Subsequently, the relationship has been characterized by a numerical model to show how to modulate the parameters of the matrix properties to achieve excellent fatigue properties of CFRP. / 博士(工学) / Doctor of Philosophy in Engineering / 同志社大学 / Doshisha University Carbon fibers Polymer reinforced composites (PMCs) Fatigue Fiber/matrix bond Fracture toughness Damage Cellulose nano fiber (CNF) Micro-fibrillated cellulose (MFC) Crack growth rate Poly vinyl alcohol (PVA) fiber Thermoelastic stress analysis (TSA) Woven fabric Filament winding Composite pressure vessel Burst pressure Digital image correlation (DIC)

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