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Some aspects on strength properties in paper composed of different pulpsKarlsson, Hanna January 2007 (has links)
<p>For papermakers, an understanding of the development of strength properties in the paper is of uttermost importance. Strong papers are desirable both in the traditional paper industry as well as in new fields of application, such as fibre-based packaging and light-weight building material. In this study, the effects of adding abaca (Musa textilis) as a reinforcement fibre for softwood pulp was investigated. Moreover, the LB Multilayer Handsheet Former for the production of stratified sheets was evaluated and used to study the effects of placing selected fibres in separate layers, rather than by making homogeneous sheets from a mixture of the pulps.</p><p>Handsheets of a softwood sulphate pulp with the addition of abaca fibres were made in a conventional sheet former. It was seen that the addition of abaca fibres can increase the tearing resistance, fracture toughness, folding endurance and air permeance. Tensile strength, tensile stiffness and tensile energy absorption, however, decreased somewhat.</p><p>It was shown that the LB Multilayer Handsheet Former is suitable for studying the effects of stratification of paper. The sheet former produces sheets with good formation and the variation of paper properties of the sheets is retained at a fairly constant level when the number of layers in the stratified sheets is increased. The uniformity of the sheets produced in the LB Multilayer Handsheet Former are generally at the same level as of those produced in conventional sheet formers.</p><p>Homogeneous and stratified sheets were produced in the LB Multilayer Handsheet Former and it was found that by stratifying a sheet, so that pulp with a high tear index and pulp with a high tensile index are placed in separate layers, it was possible to increase the tear index by approximately 25%, while the tensile index was decreased by 10-20%.</p>
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Some aspects on strength properties in paper composed of different pulpsKarlsson, Hanna January 2007 (has links)
For papermakers, an understanding of the development of strength properties in the paper is of uttermost importance. Strong papers are desirable both in the traditional paper industry as well as in new fields of application, such as fibre-based packaging and light-weight building material. In this study, the effects of adding abaca (Musa textilis) as a reinforcement fibre for softwood pulp was investigated. Moreover, the LB Multilayer Handsheet Former for the production of stratified sheets was evaluated and used to study the effects of placing selected fibres in separate layers, rather than by making homogeneous sheets from a mixture of the pulps. Handsheets of a softwood sulphate pulp with the addition of abaca fibres were made in a conventional sheet former. It was seen that the addition of abaca fibres can increase the tearing resistance, fracture toughness, folding endurance and air permeance. Tensile strength, tensile stiffness and tensile energy absorption, however, decreased somewhat. It was shown that the LB Multilayer Handsheet Former is suitable for studying the effects of stratification of paper. The sheet former produces sheets with good formation and the variation of paper properties of the sheets is retained at a fairly constant level when the number of layers in the stratified sheets is increased. The uniformity of the sheets produced in the LB Multilayer Handsheet Former are generally at the same level as of those produced in conventional sheet formers. Homogeneous and stratified sheets were produced in the LB Multilayer Handsheet Former and it was found that by stratifying a sheet, so that pulp with a high tear index and pulp with a high tensile index are placed in separate layers, it was possible to increase the tear index by approximately 25%, while the tensile index was decreased by 10-20%.
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Preparation of Methylcellulose from Annual PlantsYe, Daiyong 30 September 2005 (has links)
Este trabajo presenta los resultados de la investigación sobre la preparación y caracterización de las metilcelulosas a partir de las plantas anuales.Las pastas del miscanthus, el cardo, y el eucalipto, se prepararon mediante el proceso IRSP (Impregnation Rapid Steam Pulping) y se blanquearon con las secuencias del TCF (Total Chloride Free), que usan peróxido de hidrógeno y hidróxido de sodio (NaOH). Con el aumento de la severidad del proceso de obtención de las pastas, la accesibilidad y la reactividad de las pastas aumentaron mientras que la viscosidad y el número de la kappa disminuyeron. Se desarrolló un nuevo y sencillo método de metilación para preparar las metilcelulosas a partir de la madera y las plantas anuales en el laboratorio. Cada metilcelulosa de las pastas blanqueadas con las secuencias del TCF se sintetizó en una mezcla de isopropanol con metano de yodo a 600C durante 22 horas después la pasta del TCF se mercerizó en una solución del hidróxido de sodio al 40% durante 1 hora. La mercerización y la metilación se repitieron para obtener un grado de sustitución (DS) más alto. Los resultados de la espectroscopía infrarroja de transformada de Fourier (FTIR) (Fourier Transform Infrared Spectroscopy) mostraron que los grupos del OH de la celulosa habían sido sustituidos parcialmente por grupos del metoxil. Los modelos de sustitución supramolecular de las metilcelulosas se determinaron mediante espectroscopía de resonancia magnética nuclear del carbono-13. La viscosidad intrínseca de las metilcelulosas se midió con agua destilada, una solución al 4% de NaOH, o DMSO. Las propiedades reológicas de las metilcelulosas se midieron con DMSO, una solución al 4% de NaOH o agua destilada. Las metilcelulosas sintetizadas tenían unas propiedades similares a las metilcelulosas comerciales. Los volúmenes hidrosolubles y alcalinosolubles de la metilcelulosas se determinaron mediante extracción con disolventes.Las metilcelulosas se prepararon a partir de pastas de lino, yute, cáñamo, sisal, y abacá mediante metilaciones heterogéneas y homogéneas. Estas pastas se blanquearonmediante el proceso ECF (Elemental Chlorine Free). La mutilación inhomogénea de las pastas blanqueadas mediante el proceso ECF se sintetizó en una mezcla de isopropanol con metano de yodo a 600C durante 22 horas después la pasta del ECF se mercerizó durante 1 hora en una solución de NaOH al 50%. La mutilación homogénea de la pasta blanqueada mediante ECF se realizó en DMSO con metano de yodo a 300C durante 48 horas. Para esta metilación homogénea se usó una metilcelulosa con un grado de sustitución más bajo, que se disolvió completamente en DMSO. La espectroscopía infrarroja de transformada de Fourier (FTIR) de las metilcelulosas mostró la existencia de grupos de metoxiles sobre las moléculas de metilcelulosa. Se utilizó la espectroscopia de resonancia magnética nuclear del carbono 13 para medir los grados de sustitución de las metilcelulosas. Los pesos moleculares de las metilcelulosas hidrosolubles se determinaron con la cromotagrafía de exclusión por tamaños (SEC). Las viscosidades intrínsecas se midieron en una solución de NaOH al 4%. Las metilcelulosas preparadas a partir de pastas de elevadas accesibilidades y reactividades tenían las mejores grados de sustitución, pesos moleculares, viscosidades y viscosidades intrínsecas.Se investigaron las accesibilidades y reactividades de las pastas del ECF. Los volúmenes de glucosa y de xilosa de estas pastas se determinaron mediante HPLC (High performance liquid chromatography) después de la hidrólisis. Las accesibilidades de adsorción de yodo de estas pastas eran bajas y sus fragmentos accesibles estaban entre el 1,31% y el 5,16%. En la región amorfa, sus fragmentos accesibles estaban entre el 5% y el 24%. Las imágenes del SEM (Scanning Electrón Microscopy) mostraron que sus fibrillas tenían distintas estructuras morfológicas. Los resultados de la espectroscopía infrarroja de transformada de Fourier (FTIR) mostraron que, después de los pretratamientos, habían disminuido tanto la media de la intensidad de los enlaces de hidrógeno como los índices de cristalinidad relativos. Sus reactividades aumentaron significativamente después de la mercerización preliminar. Las accesibilidades y reactividades de la pasta del abacá se mejoraron con los tratamientos de impregnación con agua, la mercerización a 15 bares de presión, la explosión de vapor y la mercerización preliminar. La desintegración, el incremento de los huecos, el debilitamiento de la intensidad de los enlaces de hidrógeno, la depolimerización, y la decristalización son esenciales para mejorar las accesibilidades y las reactividades, pero el factor decisivo es la especie de la planta.Hemos estudiado los factores que influyen en el peso molecular (Mw) de las metilcelulosas hidrosolubles preparadas a partir de plantas anuales. El tiempo y la temperatura de impregnación y las condiciones de cocción influyeron de manera diferente en el peso molecular (Mw) de metilcelulosas preparadas a partir de los cardos recogidos en primavera y en verano, el miscanthus y el eucalipto. Se compararon los efectos de los pretratamientos (la impregnación con agua, la mercerización preliminar, la mercerización con presión y la explosión de vapor) en la pasta del abacá. Cuando se pretrató la pasta del abacá, su metilcelulosa hidrosoluble consiguió un peso molecular más alto. De entre los pretratramientos analizados, la explosión de vapor resultó el más adecuado. Para conseguir metilcelulosas con un peso molecular más alto deben perfeccionarse las condiciones de la preparación de las pastas blanqueadas mediante ECF. La especie de las plantas es el factor decisivo para conseguir el peso molecular más alto de las metilcelulosas y para seleccionar los pretratamientos más adecuados.Los parámetros del proceso de obtención de pastas, las condiciones de la metilación, las especies de las plantas, los pretratamientos, y la estructura morfológicas de las pastas influyó en los grados de sustitución de las metilcelulosas preparadas a partir de plantas anuales. Una severidad de impregnación más alta, una temperatura del proceso de obtención de pastas más alta y un incremento del tiempo del mismo proceso consiguieron grados de sustitución más altos. Un aumento de reactivos de la metilación causó un aumento de grado de sustitución. Las pastas obtenidas de distintas especies produjeron grados de sustitución diferentes, trabajando con las mismas condiciones de metilación. Los pretratamientos aumentaron el grado de sustitución de las metilcelulosas.Esta investigación contribuye a encontrar las condiciones apropiadas para metilcelulosas diseñadas a medida, sintetizadas a partir de plantas anuales. Esta investigación demuestra que estas plantas tienen la capacidad de ser preparadas para conseguir metilcelulosas de alta calidad y de alto valor aptas para distintas aplicaciones, como la industria alimentaria, la de la construcción o la farmacéutica. La industria puede utilizar estas plantas anuales de crecimiento rápido para producir metilcelulosas, con lo que, además, se evitará el uso de madera.Palabras clave: abacá, accessibilidad, blanqueo mediante TCF, cáñamo, cardo, eucalipto, grado de sustitución, lino, metilación, metilcelulosa, miscanthus, peso molecular, plantas anuales, proceso de obtención de pasta IRSP, sisal, yute. / Preparation and characterization of methylcelluloses from some annual plantswere investigated.Miscanthus, cardoon, and eucalyptus pulps were produced by Impregnation Rapid Steam Pulping (IRSP) process and bleached by Total Chloride Free (TCF) sequences using hydrogen peroxide and sodium hydroxide. With an increase of pulping severities, accessibilities and reactivities of bleached pulps increased while viscosities and kappa numbers decreased. A novel facile methylation was developed in order to prepare methylcelluloses from wood and annual plants. Each methylcellulose of TCF bleached pulps was synthesized in isopropanol slurry with iodomethane at 600C for 22 hours after the TCF bleached pulp was mercerized in 40% NaOH solution for 1 hour. The mercerization and methylation were repeated in order to obtain a higher degree of substitution (DS). Fourier Transform Infrared (FTIR) spectra showed OH groups of cellulose were partially substituted by methoxyl groups. Supramolecular substitution patterns of methylcelluloses were determined by 13C nuclear magnetic resonance (NMR) spectroscopy. Intrinsic viscosities of methylcelluloses were measured in distilled water, 4% NaOH solution, or dimethyl sulphoxide (DMSO). Rheological properties of methylcelluloses were measured in DMSO, 4% NaOH solution or distilled water, in which the synthesized methylcelluloses had similar properties as commercial methylcelluloses. Watersoluble and alkali-soluble contents of methylcelluloses were determined by solventextraction.We used iodomethane to synthesize methylcelluloses from Elemental Chloride Free (ECF) bleached abaca, hemp, flax, jute, and sisal pulps via heterogeneous and homogeneous methylations. The heterogeneous methylation was carried out in isopropanol with iodomethane at 600C for 22h after a ECF bleached pulp was mercerized in excessive 50% NaOH solution for one hour at ambient temperature. The homogeneous methylation was carried out in dimethyl sulfoxide with iodomethane at 300C for 48h using a methylcellulose of low degree of substitution. Fourier Transform Infrared (FTIR) spectra of the synthesized methylcelluloses showed the existence of methoxyl groups on methylcellulose molecules. The degrees of substitution of the synthesized methylcelluloses were measured by 13C Nuclear Magnetic Resonance (NMR) spectroscopy. The molecular weights of the waterVI soluble methylcelluloses were determined by Size Exclusion Chromatography (SEC). Intrinsic viscosities of the synthesized methylcelluloses were measured in 4% NaOH solution. Methylcelluloses with better properties, such as greater degrees of substitution, molecular weights, viscosities, and intrinsic viscosities, were prepared from the pulps with higher accessibilities and reactivities. The factors influencing the preparation of methylcelluloses from these pulps were discussed.Pretreatments (water-soaking, pre-mercerization, mercerization under a pressure of 15 bars, and steam explosion) were used to improve the accessibilities and reactivities of celluloses of bleached flax, hemp, sisal, abaca, and jute pulps for the synthesis of methylcellulose. Glucose and xylose contents of these pulps were determined by High Performance Liquid Chromatograph (HPLC) after hydrolysis. Degrees of crystallinity of these pulps were determined by X-ray Diffraction (XRD) spectra. Figures of Scanning Electron Microscope (SEM) showed that their fibrils had different morphological structures. The iodine adsorption accessibilities of these pulps were low and accessible fractions ranged from 1.3% to 5.2%. Accessible fractions in amorphous cellulose were calculated in the 5% to 18% range. The accessibilities of these pulps were hemp pulp > flax pulp > sisal pulp > jute pulp > abaca pulp. Fourier Transform Infrared (FTIR) spectra showed that mean hydrogen bond strengths were weakened and relative crystallinity indexes were decreased by pretreatments. The accessibility and reactivity of the abaca pulp were improved by water soaking, mercerization under 15 bars pressure, steam explosion and preliminary mercerization, of which steam explosion and pre-mercerization were thebest treatments. Species was the main factor for the accessibility and reactivity.We studied the factors that influenced the molecular weights (Mw) of watersolublemethylcelluloses prepared from annual plants and juvenile eucalyptus. Miscanthus and cardoon stalks, and bleached pulps of abaca, jute, sisal, hemp, and flax were used as the annual plant materials. A higher concentration of NaOH solution during the impregnation led to a spring cardoon methylcellulose having a lower molecular weight. As the impregnation times increased, so did the molecular weights of the water-soluble methylcelluloses of spring cardoon. The impregnation conditions had less influence on the methylcelluloses of summer cardoon than on the methylcelluloses of spring cardoon. As the cooking times increased, so did the molecular weights of miscanthus methylcelluloses. A lower pulping severity increased the molecular weight of eucalyptus methylcellulose. The preliminary treatments (water soaking, pre-mercerization, mercerization under pressure andsteam explosion) improved the molecular weights of water-soluble abaca methylcelluloses. The steam explosion method was the best of the preliminary treatments for the abaca pulp. Different species led to different molecular weights for methylcelluloses synthesized from ECF bleached pulps, and these were further improved by preliminary mercerization. The molecular weight of -cellulose methylcellulose changed as the ratio of the methylation reagent was varied. In order to synthesize an optimum Mw of methylcellulose, the different raw materials can be chosen, the pulping parameters adjusted (including impregnation and cooking), the cellulose pretreated, and the methylcellulose conditions changed. The plant species is the decisive factor for the Mw of methylcellulose.The pulping parameters, the methylation conditions, the species, the pretreatments, and the morphological structures of pulps influenced the degrees of substitution of the methylcelluloses prepared from the annual plants. A higher impregnation severity, a higher pulping temperature, and a longer pulping time caused a higher degree of substitution. An increase of methylation reagents led to an increase of degree of substitution. Methylcelluloses of different degrees of substitution were synthesized from the pulps of different species when a same methylation condition was used. The pretreatments increased the degrees of substitution of methylcelluloses.This investigation contributes to find appropriate conditions for the production of methylcellulose from annual plants. The present investigation demonstrates these annual plants have the capacities to produce upgraded and high quality methylcelluloses for varied applications, such as additives of foods, construction, pharmaceutics, polymerization, paints, and detergents etc. The industry can utilize these annual fast-growth plants to produce methylcelluloses. Therefore, a lot of wood will be saved.Keywords: abaca, accessibility, annual plants, cardoon, degree of substitution, eucalyptus, flax, hemp, IRSP pulping, jute, methylation, methylcellulose, miscanthus, molecular weight, sisal, steam explosion, TCF bleaching.
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Non-wood fibers for strength enhancement of paper : Mixing softwood pulp with abaca, sisal and banana fibersRinaldo, Emilia January 2020 (has links)
The aim with this master thesis was to investigate the potential of using non-wood fibers to enhance the paper strength. Abaca, sisal and banana fibers were added to conventional bleached chemical softwood pulp. The effect of refining was investigated, both as co-refining and as separate refining. The fiber properties were determined with a Fiber Tester and the drainage resistance was determined with Schopper-Riegler. Density, tensile index, tear index and burst index were determined on paper sheets made in a Rapid-Köthen sheet former. The results showed that abaca had longer fiber length than softwood, while sisal had slightly shorter fiber length compared with softwood. Sheet density was lowered with addition of all three fiber types, while the drainage resistance was increased for the same. It was also observed that the tensile index increased with additions of abaca, while additions of sisal and banana fibers gave lower tensile indexes. The same trend was observed for the tear index and burst index. Refining gave higher values of the drainage resistance, density, tensile index and burst index. However, the tear index was affected differently depending on the fiber type and fiber blend. For sisal and banana fibers, the tear index was first increased at lower refining degrees and were thereafter decreased with further refining. When studying abaca and softwood, a declining trend was observed over the entire refining interval. The conclusion was that addition of abaca fibers increased all investigated strength properties. Sisal and banana fibers gave higher values of the tear strength, when exposed to mild refining.
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Abaca in the Philippines, an overview of a potential important resource for the country : Relating the tensile strength of the single fiber to the microfibrilar angleWaller, Victor, Wilsby, Astrid January 2019 (has links)
Due to environmental concerns and to the limited amount of fossil fuel in the world theinterest in using renewable material has been and will continue to be on the rise. With theincreasing demand for renewable materials such as bio-based fibers, the research aroundnatural fibers is intensifying. Abaca (Musa Texitilis Nee) is a plant endemic to the Philippineswhich is claimed to contain the strongest natural fiber in the world 1. However, no thoroughresearch on performing tensile strength test on single abaca fibers/cells has been found. Byperforming tensile strength test on the single abaca fibers and relate this will provide freshdata about the single abaca fiber strength that can be compared with other natural fibers.This can later be a reference tool in order to find the optimal fiber for the product to be made. The purpose of this study is to develop a methodology for performing tensile strength testson single abaca fibers with the major objective to relate the tensile strength and E-modulusof the fibers with their microfibrillar angle (MFA). The research was done by using Abaca(grade S2) from Camarines Sur (Philippines) that was chemically disintegrated in order toobtain single fibers. The single fibers were mounted to a custom made paper frame for thetensile strength test performed by an Instron 5944. The MFA of each fiber was also retrievedusing an optical microscope with a polarized filter. The research showed an indication of aninversely proportional relation between MFA and tensile strength of the fibers. According tothe results, the E-modulus of the single abaca fiber was almost constant, independently onthe MFA of the fiber. / The purpose of this study is to do a broad map out of the abaca industry in the Philippines. Furthermore, the study aims to provide an overview of the abaca industry as a tool for finding ways to optimize the fiber production and to find suggestions on how to make a bigger share of the profit from the abaca products to stay by the farmers in the Philippines. The objectives are therefore also focused on describing the way the abaca plant is cultivated, harvested, processed, and further distributed from the farms. Also, the objectives are to describe the abaca supply and demand situation along with identifying challenges for abaca production. Today the outmoded abaca production in the Philippines is experiencing a productivity loss which makes the farmers' incomes unnecessarily low. Important factors that, by this study, have been identified affecting the low productivity and profit are lack of proper farming management, distribution and unoptimized usage of the fibers. A big share of the abaca fibers produced is also being exported. This means that the raw fibers are being made into high-value products abroad and hence the profit to be made is dislocated further from the farmers with low means of improving their standard of living. The study has been performed by doing a literature study complemented with interviews and visits to abaca farmers and other stakeholders within the abaca industry.
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Investigation into non-aqueous remedial conservation treatments for iron-tannate dyed organic materialsWilson, Helen Louise January 2013 (has links)
Iron-tannate dyes have been used for thousands of years and on many continents to colour materials that are now part of our cultural heritage shades of black, grey, or brown. Cellulosic and proteinaceous yarns and woven textiles have been dyed with iron-tannate dyes to form objects or components of objects for domestic and ceremonial use. Unfortunately, the longevity and useful lifetime of iron-tannate dyed objects is threatened by the dye itself which accelerates the degradation of organic materials through metal-catalysed oxidation and acid-catalysed hydrolysis. The accelerated degradation causes weakening, discolouration, and embrittlement of the organic materials at a faster rate than undyed equivalents and if left unimpeded, weakens the objects to the point that they are no longer able to be exhibited without damage. In some cases the degradation is so great that the dyed areas of the objects have crumbled to dust. At present there is no suitable chemical stabilisation method available with which to inhibit this degradation. An aqueous treatment is available for successfully stabilising paper containing iron gall ink; iron gall ink is chemically similar to iron-tannate dye. However, the aqueous nature of this treatment makes it unsuitable for weakened fibres, water soluble components, and water sensitive materials which may be part of a composite material containing iron-tannate dye. Non-aqueous treatments are therefore urgently needed in order to preserve our iron-tannate dyed cultural heritage for future generations.In this project a range of non-aqueous antioxidants and a non-aqueous deacidifier (described in Chapter 8) were tested alongside existing aqueous treatment in order to establish their ability to slow down the degradation of a range of model iron-tannate dyed textiles (Chapters 9 and 10). Model textiles were developed as part of the project (Chapters 3-5) to be substitutes for historic materials in these stabilisation studies. Validation of the model textiles for this purpose (Chapter 6) involved the comparison of the model textiles with selected historic iron-tannate dyed objects within the British Museum’s collection (Chapter 6). The historic objects and the properties of the model textiles before and after accelerated ageing (Chapters 5 and 6) and before and after treatment application (Chapters 9 and 10) have been characterised using a variety of analytical techniques (Chapter 2). In order to determine which accelerated ageing conditions were the most suitable for this project various combinations of elevated temperature and either cycling or stable relative humidity were tested for their ability to produce noticeable changes in the properties of the dyed model textiles within four weeks of ageing (Chapter 7). This project is an AHRC/EPSRC funded Science and Heritage Programme PhD in which the British Museum has been a collaborative institution. Among other wider dissemination methods, research from this project has been presented to the public on numerous occasions at gallery tours and Science Day events at the British Museum.
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Síntesis de carboximetilcelulosa (CMC) a partir de pastas de plantas anualesBarba Pacheco, Claudia 28 June 2002 (has links)
Palabras clave: materiales lignocelulósicos residuales, chopo, pino, paja de trigo, plantas anuales, abacá, sisal, yute, lino, Miscanthus sinensis, bagazo de caña de azúcar, henequén, pastas de cocción rápida sosa/AQ, pastas IRSP, carboximetilcelulosa, comportamiento reológico, grado de sustitución.El presente trabajo describe la preparación y caracterización de muestras de carboximetilcelulosa (CMC) a partir de diferentes materiales lignocelulósicos tanto residuales como no madereros, así como el estudio de la influencia de las condiciones de preparación de la materia de partida y sus características sobre las propiedades finales de las CMCs obtenidas. La producción de carboximetilcelulosa a partir de estos materiales supone una importante contribución ya que, en la mayoría de los casos, el derivado se obtiene a partir de linters de algodón y madera de pino y eucalipto. Las muestras de CMC fueron preparadas a partir de pastas procedentes de tres diferentes tipos de cocciones:  Pastas blanqueadas de pino, chopo y paja de trigo, provenientes de procesos de cocción con sosa/antraquinona con tiempos de residencia que abarcaban desde los convencionales de aproximadamente 90 min hasta tiempos de cocción rápidos del orden de 3 min. Pastas blanqueadas de Miscanthus sinensis, bagazo de caña de azúcar y henequén cocidas mediante el método IRSP (Impregnation Rapid Steam Explosion Process) Pastas papeleras comerciales y blanqueadas provenientes de procesos convencionales sosa/antraquinona de abacá, sisal, yute y lino La reacción de eterificación se llevó a cabo siguiendo el procedimiento Druvacell a escala laboratorio para la obtención de CMC con alto grado de pureza. Esta se realizó utilizando siempre las mismas condiciones de operación y relación cuantitativa de los materiales presentes. Los productos purificados fueron caracterizados en función de su grado de sustitución (DS), pureza, solubilidad, viscosidad intrínseca  de soluciones de CMC en NaCl 0.1M, peso molecular y comportamiento reológico de soluciones de CMC a diferentes concentraciones. Se encontró que el DS de las CMCs sintetizadas en el laboratorio dependen en gran medida de la morfología del material lignocelulósico del cual provienen. El método usado para la eterificación de las pastas, da como resultado DS cercanos a 1 después de una eterificación y alrededor de 2 si se aplica un segundo tratamiento de eterificación. Con excepción de las CMCs fabricadas a partir de Miscanthus sinensis y bagazo de caña de azúcar, se obtuvieron DS de 0.75 y 1.45 después de una y dos eterificaciones respectivamente. La pureza de todas las muestras de CMC superaba el 98%. Los valores del peso molecular y el comportamiento reológico de las soluciones de CMC están relacionados con la viscosidad de las pastas de partida. De esta manera, las pastas que tenían un valor menor de viscosidad generaban CMCs con un comportamiento reológico cercano al newtoniano y por el contrario las CMCs que fueron sintetizadas a partir de pastas con mayor viscosidad, presentaban comportamientos pseudoplásticos. Los resultados relacionados con la caracterización reológica de las muestras de CMC, muestran que es posible obtener derivados de celulosa de pastas no madereras con propiedades diferentes a las obtenidas por materiales comunes como la madera o linters de algodón. Estos nuevos materiales presentan un potencial importante para la producción de derivados de celulosa con características innovadoras para aplicaciones industriales específicas, especialmente la estabilidad de la viscosidad con la temperaturaEn general, los experimentos realizados mostraron la viabilidad de obtener CMCs similares a las comerciales partiendo de materiales no convencionales. Además, se confirma la posibilidad de producir derivados de celulosa a partir de pastas de cocción rápida y explosión con vapor, ampliándose de esta manera las opciones de estudio de otros derivados de celulosa de interés industrial. / Keywords: waste lignocellulosic materials, poplar, pine, wheat straw, annual plants, abaca, sisal, jute, linen, Miscanthus sinensis, sugar cane, henequen, fast soda/AQ pulps, IRSP pulps, carboxymethylcellulose, rheological behavior, degree of substitution.In this manuscript we describe the synthesis and characterization of carboxymethylcellulose (CMC) samples from different lignocellulosic residual and non-wood materials. We also describe how the condition of the raw materials affects the preparation and final properties of the CMCs produced. The production of carboxymethylcellulose from these materials is an important contribution because, currently, it is produced from cotton linters and pine and eucalyptus wood.The CMC samples were prepared from three kinds of cellulose pulps:  Soda/anthraquinone bleached pine, poplar and wheat straw pulps with cooking residence times ranging from 3 to 90 min. Steam exploded Miscanthus sinensis, sugar cane and henequen pulps cooked by IRSP (Impregnation Rapid Steam Explosion Process). Commercial bleached paper pulps cooked by the soda/anthraquinone process of abaca, sisal, jute and linen.High purity carboxymethylcellulose was obtained by the etherification Druvacell process on a laboratory scale, always under the same conditions and with the same chemical amounts.The final purified products were characterized in terms of their degree of substitution (DS), purity and solubility in concentrated NaOH, CMC intrinsic viscosity  in 0.1M NaCl solutions, molecular weight and rheological behavior of CMC samples at different concentrations.We found that the DS depended on the raw material morphology and properties and not on the cooking temperature of the pulp source. The method we used for the etherification reaction yielded CMCs whose degree of substitution was close to 1 after one etherification reaction, and around 2 when a second etherification reaction was performed at the same conditions. Miscanthus sinensis and sugar cane were the only exceptions because they yielded CMCs with a DS of around 0.75 and 1.45 after one and two etherification treatments. All CMC samples had purities of over 98%. The molecular weights and the rheological behavior of the CMC solutions were directly related to the viscosity of the pulps. Pulps of lower viscosity therefore produced CMCs whose rheological behavior was similar to Newtonian behavior. On the other hand, the pseudoplastic behavior was obtained from pulps of higher viscosity.The rheological characterization of the CMC samples shows the viability of obtaining carboxymethylcellulose from non-conventional materials whose characteristics are different from those obtained from common materials such as wood or cotton. These new materials have great potential for producing cellulose derivatives with novel characteristics like temperature stability that make them suitable for specific and tailor-made industrial applications. Overall, our results show that carboxymethylcelluloses can be obtained from non-conventional materials having similar characteristics to commercial CMC. We also confirm the production of CMC from rapid soda/AQ and IRSP pulps, being posible to extend this study for other cellulose derivatives of industrial interest.
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Strength Properties of Paper produced from Softwood Kraft Pulp : Pulp Mixture, Reinforcement and Sheet StratificationKarlsson, Hanna January 2010 (has links)
For paper producers, an understanding of the development of strength properties in the paper is of uttermost importance. Strong papers are important operators both in the traditional paper industry as well as in new fields of application, such as fibre-based packaging, furniture and light-weight building material. In the work reported in this thesis, three approaches to increasing paper strength were addressed: mixing different pulps, multilayering and reinforcement with man-made fibres. In specific: The effects of mixing Swedish softwood kraft pulp with southern pine or with abaca (Musa Textilis) were investigated. Handsheets of a softwood kraft pulp with the addition of abaca fibres were made in a conventional sheet former. It was seen that the addition of abaca fibres increased the tearing resistance, fracture toughness, folding endurance and air permeance. Tensile strength, tensile stiffness and tensile energy absorption, however, decreased somewhat. Still it was possible to add up to about 60% abaca without any great loss in tensile strength. As an example, with the addition of 30% abaca, the tear index was increased by 36%, while the tensile index was decreased by 8%. To study the effect of stratification, a handsheet former for the production of stratified sheets, the LB Multilayer Handsheet Former was evaluated. The advantage of this sheet former is that it forms a stratified sheet at low consistency giving a good ply bond. It was shown to produce sheets with good formation and the uniformity, evaluated as the variation of paper properties, is retained at a fairly constant level when the number of layers in the stratified sheets is increased. The uniformity of the sheets produced in the LB Multilayer Handsheet Former is generally at the same level as of those produced in conventional sheet formers. The effects of placing southern pine and abaca in separate layers, rather than mixing them homogeneously with softwood pulp were studied. Homogeneous and stratified sheets composed of softwood and southern pine or softwood and abaca were produced in the LB Multilayer Handsheet Former. It was found that by stratifying a sheet, so that a pulp with a high tear index and a pulp with a high tensile index are placed in separate layers, it was possible to increase the tear index by approximately 25%, while the tensile index was decreased by 10-20%. Further, by mixing a pulp with less conformable fibres and no fines with a pulp with more flexible fibres and fines, a synergy in tensile strength (greater strength than that predicted by linear mass fraction additivity) was obtained. The effects of stratifying sheets composed of softwood and abaca were compared to the effects of refining the softwood pulp. Homogeneous and stratified sheets composed of softwood with three different dewatering resistances and abaca were also produced in the LB Multilayer Handsheet Former. It was found that by stratifying the sheets the tear index was retained while the tensile index was increased by the refining. The effects of reinforcing softwood pulp of different dewatering resistances with man-made fibres with low bonding ability were also investigated. Man-made fibres (i.e. regenerated cellulose, polyester and glass fibres) were added in the amounts 1, 3, or 5 wt% to softwood pulp of three different dewatering resistances. It was found that with refining of a softwood pulp and subsequent addition of long fibres with low bonding ability the tensile-tear relationship can be shifted towards higher strength values. The bonding ability of the man-made fibres was evaluated by pull-out tests and the results indicated that, in relation to the fibre strength, regenerated cellulose (lyocell) was most firmly attached to the softwood network while the glass fibres were most loosely attached.
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