The impact of paper constituents on the efficiency of mechanical strengthening by polyaminoalkylalkoxysilanes

The aim of the research was to evaluate the influence of certain components of paper such as lignin and papermaking additives (fillers and sizing) on the efficiency of a recently proposed treatment for simultaneous deacidification and mechanical strengthening with polyaminosiloxane copolymer network...

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Veröffentlicht in:	Cellulose (London) 2017-12, Vol.24 (12), p.5671-5684
Hauptverfasser:	Piovesan, Camille, Fabre-Francke, Isabelle, Dupont, Anne-Laurence, Fichet, Odile, Paris-Lacombe, Sabrina, Lavédrine, Bertrand, Cheradame, Hervé
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Sprache:	eng
Schlagworte:	Additives Binary mixtures Bioorganic Chemistry Bonding strength Ceramics Chemical bonds Chemical Sciences Chemistry Chemistry and Materials Science Composites Copolymers Durability Efficiency Endurance Fillers Folding Glass Lignin Mechanical properties Natural Materials Organic Chemistry Original Paper Papermaking Physical Chemistry Polymer Sciences Polymers Sizing Submerging Sustainable Development
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container_title	Cellulose (London)
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creator	Piovesan, Camille Fabre-Francke, Isabelle Dupont, Anne-Laurence Fichet, Odile Paris-Lacombe, Sabrina Lavédrine, Bertrand Cheradame, Hervé
description	The aim of the research was to evaluate the influence of certain components of paper such as lignin and papermaking additives (fillers and sizing) on the efficiency of a recently proposed treatment for simultaneous deacidification and mechanical strengthening with polyaminosiloxane copolymer networks. Mixed mechanical and chemical pulp papers containing various additives were treated with aminoalkylalkoxysilanes (AAAS) by immersion or by spray. Upon treatment, the deposited alkaline reserve varied from 0.34 to 1.14 mol kg −1 . For all the papers, copolymers formed from binary mixtures of a di- and a tri-functional AAAS provided the best improvement in the mechanical properties, i.e. in the tensile strength and the folding endurance, indicating an increase in the interfiber bonding energy and in the paper flexibility and plasticity, respectively. It was found that fillers had no influence while sizing hampered the efficiency of the treatment. The presence of mechanical pulp was shown to have a significant impact on the effect of the treatments as well by increasing the tensile resistance more than the folding endurance, indicating an increase in the paper rigidity. This observation was attributed to the response of lignin to the treatment.
doi_str_mv	10.1007/s10570-017-1513-5
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Mixed mechanical and chemical pulp papers containing various additives were treated with aminoalkylalkoxysilanes (AAAS) by immersion or by spray. Upon treatment, the deposited alkaline reserve varied from 0.34 to 1.14 mol kg −1 . For all the papers, copolymers formed from binary mixtures of a di- and a tri-functional AAAS provided the best improvement in the mechanical properties, i.e. in the tensile strength and the folding endurance, indicating an increase in the interfiber bonding energy and in the paper flexibility and plasticity, respectively. It was found that fillers had no influence while sizing hampered the efficiency of the treatment. The presence of mechanical pulp was shown to have a significant impact on the effect of the treatments as well by increasing the tensile resistance more than the folding endurance, indicating an increase in the paper rigidity. 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subjects	Additives Binary mixtures Bioorganic Chemistry Bonding strength Ceramics Chemical bonds Chemical Sciences Chemistry Chemistry and Materials Science Composites Copolymers Durability Efficiency Endurance Fillers Folding Glass Lignin Mechanical properties Natural Materials Organic Chemistry Original Paper Papermaking Physical Chemistry Polymer Sciences Polymers Sizing Submerging Sustainable Development
title	The impact of paper constituents on the efficiency of mechanical strengthening by polyaminoalkylalkoxysilanes
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