Influence de traitements chimiques et enzymatiques sur la dissolution de pâtes de bois dans NaOH-eau

Dos Santos, Nuno Miguel

13 December 2013

Different pulps were chemically (nitren) and biologically (enzyme) treated in order to improve the chemical accessibility and dissolution capacity in cold NaOH. The treatments effect on the pulp properties was accessed by studying the changes on their chemical and macromolecular structure and by analyzing the dissolution performance in cold NaOH.The nitren treatment has the effect of removing a large part of the xylan present in a dissolving pulp and is also removing mannans. Increasing the nitren concentrations will extract also cellulose and decrease its mean molar mass. These extractions are favorable for the dissolution in cold NaOH-water, being more effective with higher nitren concentrations. A maximum of 44.7% increase on the dissolution yield was achieved.The new enzymatic treatment shows a higher efficiency on promoting fibers accessibility to NaOH ions, (directly correlated with the enzymatic load), allowing a maximum increase of 150% on the dissolution yield. A slight decrease of the average molar mass was also seen. The different pulps reacted differently to the treatments, showing that the pulping pretreatments have an influence on the enzymatic efficiency. Using a mixture of enzymes and endoglucanase showed that the synergistic effect of these two enzymes is more effective on cellulose activation.Both nitren and enzymatic treatments are improving the pulp chemical accessibility mostly by modifying the structure of the primary wall and S1 wall. This promotes the swelling of these wood cell structures, allowing the access of the NaOH solvating ions into fiber regions not accessible on the original pulp. The nitren is disassembling the fiber surface with extraction of hemicelluloses and degrading the cellulosic structure.The use of this enzyme on the cellulose pulps activation towards dissolution in cold NaOH is of great importance. It presents a high potential in both technical, with further development and industrial implementation, and fundamental research fields, with further studies on mechanisms of cellulose activation.The work was performed in Cemef - Mines ParisTech, Sophia Antipolis, France, and TI / Hamburg University, Germany and financed by Sappi, Tembec, Lenzing, Viskase and Spontex and had support from EPNOE (European Polysaccharide Network of Excellence).

[SPI:OTHER] Engineering Sciences/Other

Dissolution de la cellulose

Paroi cellulaire du bois

Pâte à dissoudre

Nitren

Pectinaise

Hydroxyde de sodium

Influence de traitements chimiques et enzymatiques sur la dissolution de pâtes de bois dans NaOH-eau / Influence of chemical and enzymatic treatments on a variety of wood pulps on their dissolution in NaOH-water

Dos Santos, Nuno Miguel

13 December 2013

Different pulps were chemically (nitren) and biologically (enzyme) treated in order to improve the chemical accessibility and dissolution capacity in cold NaOH. The treatments effect on the pulp properties was accessed by studying the changes on their chemical and macromolecular structure and by analyzing the dissolution performance in cold NaOH.The nitren treatment has the effect of removing a large part of the xylan present in a dissolving pulp and is also removing mannans. Increasing the nitren concentrations will extract also cellulose and decrease its mean molar mass. These extractions are favorable for the dissolution in cold NaOH–water, being more effective with higher nitren concentrations. A maximum of 44.7% increase on the dissolution yield was achieved.The new enzymatic treatment shows a higher efficiency on promoting fibers accessibility to NaOH ions, (directly correlated with the enzymatic load), allowing a maximum increase of 150% on the dissolution yield. A slight decrease of the average molar mass was also seen. The different pulps reacted differently to the treatments, showing that the pulping pretreatments have an influence on the enzymatic efficiency. Using a mixture of enzymes and endoglucanase showed that the synergistic effect of these two enzymes is more effective on cellulose activation.Both nitren and enzymatic treatments are improving the pulp chemical accessibility mostly by modifying the structure of the primary wall and S1 wall. This promotes the swelling of these wood cell structures, allowing the access of the NaOH solvating ions into fiber regions not accessible on the original pulp. The nitren is disassembling the fiber surface with extraction of hemicelluloses and degrading the cellulosic structure.The use of this enzyme on the cellulose pulps activation towards dissolution in cold NaOH is of great importance. It presents a high potential in both technical, with further development and industrial implementation, and fundamental research fields, with further studies on mechanisms of cellulose activation.The work was performed in Cemef - Mines ParisTech, Sophia Antipolis, France, and TI / Hamburg University, Germany and financed by Sappi, Tembec, Lenzing, Viskase and Spontex and had support from EPNOE (European Polysaccharide Network of Excellence). / Different pulps were chemically (nitren) and biologically (enzyme) treated in order to improve the chemical accessibility and dissolution capacity in cold NaOH. The treatments effect on the pulp properties was accessed by studying the changes on their chemical and macromolecular structure and by analyzing the dissolution performance in cold NaOH.The nitren treatment has the effect of removing a large part of the xylan present in a dissolving pulp and is also removing mannans. Increasing the nitren concentrations will extract also cellulose and decrease its mean molar mass. These extractions are favorable for the dissolution in cold NaOH–water, being more effective with higher nitren concentrations. A maximum of 44.7% increase on the dissolution yield was achieved.The new enzymatic treatment shows a higher efficiency on promoting fibers accessibility to NaOH ions, (directly correlated with the enzymatic load), allowing a maximum increase of 150% on the dissolution yield. A slight decrease of the average molar mass was also seen. The different pulps reacted differently to the treatments, showing that the pulping pretreatments have an influence on the enzymatic efficiency. Using a mixture of enzymes and endoglucanase showed that the synergistic effect of these two enzymes is more effective on cellulose activation.Both nitren and enzymatic treatments are improving the pulp chemical accessibility mostly by modifying the structure of the primary wall and S1 wall. This promotes the swelling of these wood cell structures, allowing the access of the NaOH solvating ions into fiber regions not accessible on the original pulp. The nitren is disassembling the fiber surface with extraction of hemicelluloses and degrading the cellulosic structure.The use of this enzyme on the cellulose pulps activation towards dissolution in cold NaOH is of great importance. It presents a high potential in both technical, with further development and industrial implementation, and fundamental research fields, with further studies on mechanisms of cellulose activation.The work was performed in Cemef - Mines ParisTech, Sophia Antipolis, France, and TI / Hamburg University, Germany and financed by Sappi, Tembec, Lenzing, Viskase and Spontex and had support from EPNOE (European Polysaccharide Network of Excellence).

Dissolution de la cellulose

Paroi cellulaire du bois

Pâte à dissoudre

Nitren

Pectinaise

Hydroxyde de sodium

Cellulose dissolution

Wood

Nitren

Dissolving pulp

Pectinase

Sodium hydroxide

Concepts et développements pour la production de cellulose blanchie, pure ou oxydée à partir de matière lignocellulosique à recycler / Concepts and developments for the production of bleached, pure or oxidized cellulosic pulp from recycled lignocellulosic material.

Dollie, Lucas

27 May 2019

Les papiers et cartons récupérés sont aujourd’hui recyclés en nouveaux matériaux similaires, en particulier les vieux cartons sont transformés en nouveaux cartons. Riches en matière lignocellulosique, les cartons récupérés pourraient remplacer le bois dans la production de produits de plus haute valeur ajoutée. Ainsi la thèse a exploré le potentiel de procédés existants de délignification, blanchiment et purification, appliqués sur des mélanges fibreux simulant la composition de différents cartons, pour la production de pâte papetière blanchie et de pâte à dissoudre.Le traitement appliqué est composé d’une cuisson Kraft, suivie d’une séquence de blanchiment classique D0-Ep-D1 puis, dans le cas de la production de pâte à dissoudre, d’une purification de type CCE. Les cartons à traiter ayant des compositions fibreuses variables, toute l’étude a été conduite sur des mélanges fibreux modèles, composés de fibres de pâte Kraft écrue et de pâte mécanique. Dans tous les cas, des pâtes blanchies ont été produites, même si leur degré de polymérisation est parfois en deçà des standards. En revanche, les pâtes sont difficiles à purifier. Par ailleurs, il a été montré que la qualité du produit final, les performances des procédés et leur impact environnemental, dépendent de la composition fibreuse du mélange. Enfin le traitement d’un carton industriel a révélé que les charges minérales contenues dans le matériau limitent sa revalorisation.La faible qualité des pâtes blanchies obtenues a conduit à tester une autre voie de valorisation, la production de cellulose oxydée pour MFC. Un nouveau procédé de pré-oxydation pour les pâtes Kraft écrue a été développé : il combine blanchiment et oxydation du substrat dans un stade unique en utilisant le catalyseur TEMPO avec du dioxyde de chlore et de l’hypochlorite de sodium. Des MFC de qualité équivalente à celles produites à partir de pâte blanchie préoxydée par le système TEMPO/NaClO/NaBr ont été obtenues. / Today recovered papers and boards are recycled into similar products; in particular old corrugated boards are transformed into new corrugated boxes. Rich in lignocellulosic material, recovered carton boards might replace wood for the production of hgiher added-value products. The thesis investigated the potential of existing delignification, bleaching and purification processes, applied on fibre mixes simulating the composition of various carton boards, for the production of bleached paper pulp and dissolving pulp grades.The treatment was composed of a Kraft cook, followed by a conventional D0-Ep-D1 bleaching sequence, and in the case of dissolving pulp production, a CCE stage for cellulose purification. Because carton boards exhibit various fiber compositions, all the study has been conducted on model mixes, made of fibres from unbleached Kraft pulp and mechanical pulp. In all cases, bleached pulps have been successfully obtained, although pulp viscosity was sometimes below the standards. However the bleached pulps were found difficult to purify. Moreover, it has been shown that the quality of the final product, the performances of the processes and their environmental impact, depended on the fiber composition of the mix. Finally, the treatment of an industrial carton board revealed that mineral fillers contained in the material limit its upcycling.Because of the low quality of the bleached pulp produced, another valorization way was tested: the production of oxidized cellulose for MFC. A new pre-oxidation process for unbleached Kraft pulp has been developed, combining bleaching and oxidation of the substrate in a single stage combining stage combining the use of TEMPO as a catalyst, chlorine dioxide and sodium hypochlorite. MFC of same quality as those produced from bleached Kraft pulp pre-oxidized by the classical TEMPO/NaClO/NaBr system have been obtained.

Cuisson kraft

Blanchiment

Purification osidique

Recyclage des vieux cartons

Pâte à dissoudre

Mfc

Kraft cooking

Bleaching

Polysaccharides purification

Old corrugated board recycling

Dissolving pulps

Mfc

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Extraction des hémicelluloses de pâtes papetières pour la production de pâte à dissoudre / Hemicellulose extraction of paper grade pulp for dissolving pulp production

Arnoul Jarriault, Benoît

17 December 2015

Les pâtes à dissoudre, composées à 95% de cellulose, sont la matière première pour la production de fibres cellulosiques régénérées (viscose, Lyocell…) et de dérivés cellulosiques (ester, éther ou nitrate de cellulose). En tant qu’alternative aux matériaux issus de ressources pétrolières, ces produits connaissent actuellement un fort regain d’intérêt. Ainsi, la production de pâte à dissoudre devrait croître fortement au cours de la prochaine décennie. L’objectif de cette thèse est de proposer des procédés de conversion d’une pâte papetière de résineux en pâte à dissoudre. Pour cela les hémicelluloses présentes dans les pâtes kraft papetières doivent être extraites. Trois méthodes d’extraction d’hémicelluloses ont ainsi été étudiées : (1) une extraction alcaline à froid (CCE) dans des conditions non conventionnelles, (2) un procédé se divisant en deux étapes successives : un stade acide à haute température (150°C) suivie d’une extraction alcaline à chaud (AHCE) et (3) une hydrolyse enzymatique par trois enzymes commerciales (une xylanase, une mannanase, une cellulase). Les deux premières méthodes ont permis de produire des pâtes avec des caractéristiques proches des pâtes à dissoudre commerciales. Cependant, dans les trois voies d’extraction étudiées, l’extraction d’hémicelluloses n’a jamais atteint 100%. Des prétraitements des pâtes (raffinage, explosion à la vapeur, oxydation TEMPO) ont alors été testés pour améliorer l’extraction des hémicelluloses. De nouvelles séquences de purification basées sur la combinaison d’une étape de raffinage suivie d’une extraction alcaline à froid (CCE) peuvent être ainsi imaginées. La dernière partie de ces travaux de thèse s’est intéressée au gonflement des pâtes à dissoudre. Les travaux ont abouti à la création d’une nouvelle méthode simple et rapide de caractérisation du gonflement des fibres de pâte cellulosique. Cette méthode de mesure peut être, dans certaines conditions, considérée comme une mesure alternative de la réactivité des pâtes à dissoudre habituellement caractérisée par le test Fock. / Dissolving pulps, which are composed of 95% cellulose, are the raw materials for the production of regenerated cellulose fibres for textile application and for the production of cellulose derivatives. These products are alternatives to oil based materials. A growing demand in such products is expected in the next decades. Therefore, additional capacities in the production of wood dissolving pulp must be created. The purpose of this work is to develop hemicellulose removal processes with the aim to convert a softwood kraft paper pulp into a dissolving pulp. Three extraction methods were tested: (1) A cold caustic extraction process (CCE) performed under conventional and unconventional conditions; (2) A process consisting in an acid stage at high temperature (up to 150°C) followed by a hot caustic extraction (A-HCE); (3) An enzymatic hydrolysis using xylanase, mannanase, and cellulase. Conversion was quite successful with the two first processes. However, 100% of hemicellulose removal was never reached. In order to improve the hemicellulose extraction efficiency, several pre-treatments were tested (refining, steam explosion, TEMPO oxidation). The addition of a refining stage allows a reduction of the NaOH concentration during CCE extraction without affecting the hemicellulose extraction efficiency. The last part of this thesis work focus on the dissolving pulp swelling. A new and rapid test for the characterization of fibre swelling was developed. This method was used as an approach to the assessment of dissolving pulp reactivity in the viscose process in place of the Fock’s method.

Pâte à dissoudre

Extraction d'hémicelluloses

Pâte kraft

Gonflement des fibres cellulosiques

Réactivté des pâtes à dissoudre

Analyse MorFi

Dissolving pulp

Kraft pulp

Hemicelluloses extraction

Fiber swelling

Morfi analyser

Pulp reactivity

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