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Impact of degree or Polymerization of Fiber on Viscose Fiber StrengthIqbal, Shoaib, Ahmad, Zuhaib January 2011 (has links)
The aim of the study was to find out the relationship between the DP and the tensile properties of different regenerated cellulose fibers. During the process to make regenerated cellulose fibers from wood, the reduction in DP of cellulose is a necessary process to enable fiber extrusion. The reduction of the DP is usually from 1000 to 350 (Coley 1953). The reduction in DP is necessary, first to make the cellulose soluble, and then further decrease in DP is required to control the viscosity of the solution to minimize the mechanical difficulties during processing faced. It is a fact that the reduction in DP is a compromise which is necessary, as reduction in DP means reduction in tensile properties of the fiber produced. The reduction in DP is optimized to make the process both processing and the final product more feasible. The relation in DP and the strength of the fibers is rather obvious i.e. higher the DP higher the tensile strength, but researchers have different views regarding the relationship. By the experiments performed by us we tried to come to a conclusion regarding the difference in opinions. Different types of regenerated cellulose fibers were collected from various sources. Both wet and dry tenacities of 19 different viscose, bamboo viscose, kupro viscose, modal and Tencel fibers were determined. The fiber linear density was also measured, but for some samples we had to take the fiber density value as provided by the manufacturer, due to the limitation of the instrument regarding the fiber length and low fiber linear density. Then out of all the samples 10 were selected (based on our and company’s interest). SEC analysis was used to determine the DP of the samples. These tests were not carried out by us but by MoRe Research. The results of both the analysis were gathered, analyzed and commented upon. / Program: Master Programme in Textile Technology
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Cellular Function of the Ia-motoneuron Circuit Following Peripheral Nerve RegenerationBullinger, Katie Leigh 28 July 2009 (has links)
No description available.
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Arabinoglucuronoxylan and Arabinoxylan Adsorption onto Regenerated Cellulose FilmsNi, Ying 10 January 2014 (has links)
Cellulose and hemicelluloses have attracted increasing interest as renewable biopolymers because of their abundance. Furthermore, the recognition of biomass as a sustainable and renewable source of biofuels has driven research into the assembly and disassembly of polymers within plant cell walls. Cellulose thin films are useful in the study of interactions between cellulose and hemicelluloses, and quartz crystal microbalances with dissipation monitoring (QCM-D), surface plasmon resonance (SPR) and atomic force microscopy (AFM) are widely used to investigate polymer adsorption/desorption at liquid/solid interfaces.
In this study, smooth trimethylsilyl cellulose (TMSC) films were spincoated onto gold QCM-D sensors and hydrolyzed into ultrathin cellulose films upon exposure to aqueous HCl vapor. The adsorption of arabinoglucuronoxylan (AGX) and arabinoxylan (AX) onto these cellulose surfaces was studied. The effects of structure, molar mass and ionic strength of the solution were considered. Increasing ionic strength increased AGX and AX adsorption onto cellulose. While AGX showed greater adsorption onto cellulose than AX by QCM-D, the trend was reversed in SPR experiments. The combination of QCM-D and SPR data showed a greater amount of water was trapped within the AX films. Both adsorbed AGX and AX films were subsequently visualized by AFM. Images from AFM showed AGX and AX adsorbed as aggregates from water, while AGX and AX adsorbed from CaCl2 yielded smaller xylan particles with more numerous globular structures on the cellulose surfaces. Images from AFM of xylan films on bare gold surfaces also showed layers of uniform aggregates that were consistent with AX and AGX aggregation in solution. / Master of Science
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Use of ionic liquid for producing regenerated cellulose fibersJiang, Wei, master of science in textile and apparel technology 03 August 2012 (has links)
The objectives of the research are to establish the process of obtaining regenerated fibers and films from wood pulp and bagasse pulp with the ionic liquid 1-Butyl-3-methylimidazolium Chloride (BMIMCl) as a solvent; to study the impacts on tensile strength of different spinning parameters; to find the optimal spinning condition, and to obtain regenerated cellulose products with flame retardant properties. Solutions were obtained by dissolving cellulose (wood/bagasse) pulp into the BMIMCl. The solutions were extruded in a dry-jet and wet-spinning method using water as a coagulation bath. The obtained fibers were tested to evaluate the properties such as tensile strength, thermal property, thermal mechanical property, crystal order, and ionic liquid residue in obtained fiber. The orthogonal experiments were designed to find out the strongest affective variable and the optimal condition of the spinning process. The regenerated cellulose films with melamine resin or zinc oxide were obtained. Their flame retardant properties were tested. Cellulose fiber with melamine resin was also obtained. Thermo-gravimetric analyzer (TGA) was used to measure the thermal properties of obtained products, and to calculate their activation energies. Dynamic mechanical analysis (DMA) was used to determine the thermal mechanical properties of obtained fibers. Wide angle X-ray diffraction (WAXD) was used to measure the degree of crystallinity and degree of crystal orientation. The tensile strength was tested by a tensile machine. To evaluate the quantity of ionic liquid residue in the regenerated fibers, the instrumental methods of FT-IR and Mass Spectrometry were applied. Research results indicated increases in the degree of crystallinity and storage modulus under a higher fiber drawing speed. Both regenerated bagasse fibers and regenerated wood fibers had similar thermal properties. However, the regenerated bagasse fibers showed a higher degree of crystallinity and a higher tenacity than the regenerated wood fibers obtained under the same condition. The study also revealed water treatment would be helpful for eliminating the ionic residue in regenerated fibers. It was also found the concentration of cellulose in the BMIMCl solution affected the tensile strength of regenerated fiber mostly. Certain amount of melamine or zinc oxide nanoparticles contained in the cellulose matrix could improve the flame retardant property effectively. / text
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Regenerated cellulose for controlled oral drug deliveryBhatt, Bhavik Janankkumar 01 May 2012 (has links)
The performance of regenerated cellulose (RC) films and capsules was investigated for their applications in oral controlled drug delivery. Regenerated cellulose films were prepared by non-solvent-mediated, phase inversion of native and depolymerized cotton linter solutions (methylolcellulose; cellulose dissolved in dimethyl sulfoxide/ paraformaldehyde solvent system) in water as well as by phase inversion of native cotton linter solutions in organic non-solvents followed by thermal annealing. These films were monolithic in dry state and formed porous structures when hydrated. Irrespective of the degree of polymerization of the starting cellulose source or the use of organic non-solvents, the cellulose chain length was not significantly altered and cellulose was in an amorphous state. Flux analysis in diffusion cells, using ethanol-water mixtures as the solvent medium, indicated that the films take up solvent to form porous routes for transport of solute. The amount of solvent uptake required to form these routes was greater for films prepared from depolymerized cotton linter. Ionic and hydrophobic solutes traverse the films using the porous pathways following hydration of the film.
Blended RC films were prepared by combining native and depolymerized cotton linter solutions in varying ratios and phase-inverting in water, followed by thermal annealing. Porosity, pore size and water uptake of the hydrated films decreased, while the length of the transport pathway (tortuosity) increased, as the fraction of depolymerized cellulose increased in the blended films.
Differences in methylene blue dye adsorption on phase-inverted vs. phase-inverted and thermally annealed RC films indicated that the type of non-solvent utilized for phase-inversion does not affect the internal RC film structure during the phase-inversion process. However, as the boiling point of the non-solvent increased, the amount of irreversible polymer consolidation and formation non-swelling domains (hornification) increased during the thermal annealing process. This, in turn, led to reduced porosity and solute flux through these RC films.
Two-piece cellulose capsules were fabricated by phase-inversion of methylolcellulose solutions in water using a dip-coating approach. Zero-order release rates for a number of drugs increased as their water solubility increased. The release of water soluble drugs occurred by osmotically-driven convection and diffusion through the pores in the capsule wall, while the release of moderate to poorly soluble drugs predominantly occurred by diffusion. Moreover, as the drug solubility increased, the apparent permeability of the drugs through the capsule wall decreased, which indicated that the inward osmotic flux of water reduced the diffusivity of the drug through the pores. The hydraulic permeability of the cellulose capsules was determined to be higher than for conventional ethylcellulose and cellulose acetate coated osmotic drug delivery systems, indicating that the cellulose-based capsules may be better suited for osmotic drug delivery.
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BAMBUVISKOS : En hållbar fiber för framtiden? / Bamboo Viscose : a Sustainable Fibre for the Future?Svensson, Karin, Magnusson, Elin January 2013 (has links)
Naturskyddsföreningen gav författarna uppgiften att undersöka förekommande viskosprocesser och alternativa regenereringsprocesser, detta för att identifiera hur hållbara de är ur ett miljöperspektiv och vilka processer som går att applicera på bambu. Detta för att se möjligheten att märka bambuviskos med Bra Miljöval och för att klargöra frekvent uppkommande frågor angående bambuviskos. Syftet är att se på de olika processernas kemiska innehåll samt vilka utsläpp de orsakar till luft och vatten. Ett delmål med rapporten är att den ska kunna användas som material vid vidareutveckling av kriterierna för Bra Miljöval Textil. Resultat som erhållits vid jämförelser av studerad litteratur är att de betydande faktorerna för miljöpåverkan från massaframställningen samt viskos- och lyocellprocessen beror av: använda kemikalier i processen, energianvändningen och vilken typ av energi, möjligheten till rening av utsläpp till luft och vatten samt återvinning av energi och kemikalier. Beroende på vilket råmaterial som används vid massaframställningen kan skillnader i markanvändning, användning av bekämpningsmedel och gödningsmedel samt upptagande av koldioxid skilja sig. Massa- och fiberframställning bör vara integrerade då energiförbrukning och mängd kemikalier kan minskas. Energin kan dessutom återvinnas till större utsträckning.Genom miljömärkningar från oberoende organisationer blir det lättare för konsumenter att göra miljömedvetna val och veta vad märkningarna står för. Sammanfattningsvis ska det påpekas att om regenererad bambu framställs som den görs idag är den ingen hållbar fiber, men sker framställningen i en integrerad process där kemikalier och energi återvinns samt rening av utsläpp till luft och vatten sker, kan bambuviskos bli en hållbar fiber för framtiden. The Swedish Society for Nature Conservation (SSNC) gave the authors the task to investigative present viscose processes and alternative regeneration processes to identify how sustainable they are from an environmental perspective, and examine which processes that can be applied to bamboo. This to see the possibility to label bamboo viscose with “Bra Miljöval” (Good Environmental Choice), which is the eco-label of SSNC, and to clarify the frequently emerging issues concerning bamboo viscose. The aim is to look at the various processes, their chemical content and the emissions they cause to air and water. Another objective of the report is that it can be used as material for further development of the criteria for “Bra Miljöval”.Results obtained when comparing the studied literature is that the significant factors of the environmental impact from the pulp production, the viscose and lyocell processes depends on: chemicals used in the process, energy and energy source, the possibility of purifying emissions to air and water and recycling of energy and chemicals. Depending on the raw materials used for pulp production, differences in land use, use of pesticides and fertilizers as well as absorption of carbon dioxide differ. Pulp and fibre production should be integrated to reduce energy consumption and the amount of chemicals used. The energy can also be recycled to a greater extent.Eco-labels from independent organizations will make it easier for consumers to make environmentally conscious choices and be aware of what the labels stand for.In conclusion, it should be noted that if the regenerated bamboo is produced as it is today, it is not a sustainable fibre. If the production is done through an integrated process in which chemicals and energy recovery and purification of air and water occurs, bamboo viscose can be a sustainable fibre for the future. / Program: Textilingenjörsutbildningen
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Production of regenerated nanocomposite fibers based on cellulose and their use in all-cellulose compositesGarcía Vogel, Andrés January 2017 (has links)
Biobased all-cellulose composites (ACCs), in which the matrix and the reinforcement are made out of the same material, have gained a noticeable increased attention in recent years. Their successful application would solve the commonly faced challenges with natural fiber composites regarding their chemical antipathy between the hydrophilic fiber and the usually hydrophobic polymer matrix, while still keeping the advantages of being environmental friendly. Moreover, the use of man-made continuous regenerated cellulose fibers for this purpose could result in unidirectional all-cellulose composites with excellent mechanical properties. In this study, a new processing technique for unidirectional all-cellulose composites, reinforced with continuous regenerated cellulose nanocomposite fibers, has been developed, where the fibers are wound directly after the coagulation bath and then welded together while still being swelled in order to form all-cellulose composite sheets without the need of adding any additional solvent or chemicals. Scanning electron microscopy and tensile testing were used to investigate and compare the microstructure and mechanical properties, of a reference material without nanoreinforced fibers and two variants reinforced with 2 % cellulose nanocrystals (CNCs) and 2 % halloysite nanotubes (HNTs). Analysis revealed that transparent all-cellulose composites with a high compaction degree and minimal warpage during shrinkage, showing high mechanical properties could be made. However, the addition of nanoreinforcements did not lead to any improvements.
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Produkce a charakterizace regenerovaných huminových kyselin / Production and characterization of regenerated humic acidsUhrová, Anna January 2008 (has links)
Jihomoravský lignit pocházející z dolu Mír v Mikulčicích, Lignit s.r.o. byl přesítován a vybraná frakce byla modifikována tzv. mokrou cestou pomocí dvou oxidačních (HNO3, H2O2) a dvou „amfifilních“ (kyselina octová, kyselina citronová) činidel. Alkalickou extrakcí byly získány jak huminové kyseliny z neupraveného tak předupraveného lignitu (tzv. regenerované huminové kyseliny). Na základě výsledku elementární analýzy byly vypočítány C/O a C/H poměry, které společně s FTIR spektry podaly informaci o stupni alifaticity/aromaticity a dále o stupni oxidace organického uhlíku. Pomocí vysokoúčinné vylučovací chromatografie byla stanovena distribuce velikosti huminových agregátů. K objasnění procesů probíhajících v povrchové vrstvě bylo proměřeno povrchové napětí studovaných roztoků vzorků. Získaná data byla proložena Szyszkowského rovnicí a obdržené parametry poukázaly jak na povrchovou aktivitu jednotlivých huminových kyselin tak i na povahu molekul zodpovědných za snižování povrchového napětí. Pro vzájemnou korelaci dat získaných výše zmíněnými metodami byl použit Pearsonův korelační koeficient.
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An evaluation from the reformed perspective on the view of rev. Young-Hee Peck on regeneration : a dogmatic study / Woo SongSong, Woo Kwang January 2012 (has links)
Peck’s view on regeneration, that the regenerated spirit does not sin and die again, stems from his different view of human nature as such. He understands the soul to be an immaterial body, but not the spirit. Thereby he focuses on the human being in light of a unity between the spirit and the body. He also explicates human existence with the image of the relationship between master (spirit) and servant (body). Based on his belief he accepts that the spirit is created in the image of God as a simple unit. In this sense he conceives that the spirit manifests all of God’s attributes to the soul, which is also created sufficiently to receive and reveal God’s nature to the body. The body that is created with this capacity to reflect God’s attributes is capable of showing them to all creation. This government of God towards all creation can be effected due to the organic unity of the spirit and the body in the human being as instrument for God’s government.
As soon as Adam broke God’s commandment when his mind was deceived by the devil, his spirit was condemned and its subjective liability perished once and for all. Likewise, the spirit of the whole human race is condemned in Adam and died at once incorporated in Adam’s spirit. Thus, when the spirit created by God is united with its body in the mother’s womb that spirit dies, because all have part in Adam’s sin and have inherited the guilt and the sinful nature from Adam.
However, this all forms part of God’s greatest plan of salvation to establish his church once and for all. This church should be spotless, righteous, reconciled in His presence through the redemption by Jesus Christ. The Holy Spirit applies the eternal atoning death of Christ to the human spirit. Therefore the spirit is now able to live again and does not sin and die any more in the sense of the subjective liability for the mortal ‘soul and body’. As soon as the spirit is regenerated, therefore, the Holy Spirit takes this spirit as His indwelling place and powerfully begins to bear witness to the soul, so that this person can confess 000his/her sins and receive Jesus Christ as Saviour, that is, conversion.
Peck describes the regeneration of the spirit as the actual regeneration, in which the effect of sin and death is removed completely. He also depicts the regeneration of the body as the legal regeneration in the sense that any remaining influence of sin and death will be eliminated progressively through the power of the Holy Spirit and the Word of God. These effects of sin also will be demolished completely on the day of resurrection at the second coming of Christ. This indicates that Peck’s view on regeneration focuses for the human being as a whole, not only on the human spirit.
Peck regards regeneration as the mysterious work of the Holy Spirit in the sub-consciousness of humans. He also views it as a supernatural change, brought about by the power of the blood of Jesus, the Holy Spirit and the Word of God. In addition, he delineates it as an instantaneous change. When the Holy Spirit applies the redemption through Jesus Christ to the elect ones, their spirit immediately is raised from dead. This change is from death to life and has a ‘once-for-all’ character. Moreover, Peck characterises this process as a radical change.
Peck considers the spirit to be the root and the principle of life in humans. For him the regenerated spirit implies a radical change within the human being as a whole. This radical change does not stem from the human heart, but comes from the Holy Spirit who resurrected the regenerated spirit. By the mighty work of the Spirit the disposition of humans are radically changed (from the root). This happens when the spirit of the regenerated person is quickened, and he/she is unable to resist God’s saving grace, which conforms him/her into the true image of Christ.
In conclusion it can be noted that Peck’s general view of regeneration connects with that of the Reformers, although his thought of the regenerated spirit is not reflected in the general Reformed thought. Finally, the researcher may conclude that Peck’s view of the regeneration is acceptable within the Reformed Theology’s line of thought, whereas Peck’s particular view of the regenerated spirit diverges from the Reformed tradition. / Thesis (M.Th. (Dogmatics))--North-West University, Potchefstroom Campus, 2012
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Processing of dissolving pulp in ionic liquidsTywabi, Zikhona January 2015 (has links)
Submitted in fulfillment of the requirements for the degree of Doctor of Technology: Chemistry, Durban University of Technology, Durban, South Africa, 2015. / This thesis forms part of the Council for Scientific and Industrial Research, Forestry and Forest Products Research Centre (CSIR-FFP) biorefinery project which aims at developing and implementing novel industrial processes production of cellulose textile fibres.
The focus of this study is to investigate the dissolution of South African Eucalyptus raw (unbleached) and final (bleached) dissolving pulp and saw dust wood in an ionic liquid (IL) 1-ethyl-3-methylimidazolium acetate [Emim][OAc] and the co-solvents [dimethylsulfoxide (DMSO)] or [dimethylformamide (DMF)] mixtures, to obtain regenerated cellulose by the further addition of water and acetone.
The IL/co-solvent mixtures were able to dissolve the raw and final pulp samples at 120 ˚C for 6 hours whereas the sawdust wood dissolved in 10 hours. The IL/DMF mixture gave higher cellulose recoveries of 41.88 % for the raw pulp, 49.89 % for the final pulp sample and 32.50 % for sawdust wood while the IL/DMSO mixture gave a recovery of 15.25 % for the raw pulp sample, 36.25 % for the final pulp sample and 17.83 % for the sawdust wood sample.
The regenerated cellulose materials were characterized by Fourier Transformer Infrared Spectroscopy (FTIR), Nuclear Magnetic Resonance (NMR), Scanning Electron Microscopy (SEM), Thermo gravimetric Analysis (TGA) and Powder X-Ray Diffraction (pXRD), and compared with a standard microcrystalline of cellulose. It was observed that the FTIR and NMR spectra of the regenerated cellulose and MCC were similar which then indicates that no chemical reaction occurred during the dissolution and regeneration process of cellulose. SEM and X-ray diffraction (XRD) patterns of the results showed that after dissolution the cellulose I (native form), the crystalline structure was completely converted into cellulose II (amorphous) structure, and this was due to the removal of lignin and decrease in cellulose crystallinity. TGA results showed that the regenerated cellulose samples have higher char yields compared to the MCC which is due to the IL remaining in the regenerated cellulose.
It was also observed that the addition of the co-solvents decreased the viscosity of the IL mixture, facilitating dissolution of the cellulose that led to additional swelling and reduction of the recalcitrant nature of the cellulose crystalline structure and intermolecular interactions. This led to increased accessibility and dissolution of the cellulose.
The findings in this study have the potential to bring ILs closer to applications for biomass technology in particular for an economically viable dissolution method for biomass because ILs have a benefit of being easily separated from the anti-solvent, which provides a simple solution for IL recycle ability and re-use.
The novel aspect of this study is:
. This is the first study in the South African context to examine the influence of the lignin on the dissolution and regeneration of Eucalyptus sawdust wood and dissolving pulp. / D
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