Reinforcement ability of mechanical pulp fibres

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dc.contributor Aalto-yliopisto fi
dc.contributor Aalto University en
dc.contributor.advisor Hiltunen, Eero, Dr.
dc.contributor.author Lehto, Jouko
dc.date.accessioned 2012-08-30T06:31:56Z
dc.date.available 2012-08-30T06:31:56Z
dc.date.issued 2011
dc.identifier.isbn 978-952-60-4143-8 (PDF)
dc.identifier.isbn 978-952-60-4142-1 (printed)
dc.identifier.issn 1799-4942
dc.identifier.uri https://aaltodoc.aalto.fi/handle/123456789/4976
dc.description.abstract The objective of this study was to find out the reasons why the long fibres of mechanical pulp do not seem to reinforce paper as effectively as chemical reinforcement pulp. A preliminary laboratory trial showed that artificially increasing the average fibre length of TMP pulp by adding long fibres extracted from the same pulp increased the tear index, but decreased the tensile strength, internal bond strength and the fracture energy. Increasing the average fibre strength with chemical (NBSK) pulp fibres improved all of those properties considerably. In the second trial fibre properties and reinforcement ability of various mechanical pulps were investigated. It was shown that fibre dimensions of mechanical pulp fibres did not differ essentially from chemical pulp fibres. The biggest differences were in the properties characterizing the cell wall structure. This was clearly seen in fibre flexibility and fibre swelling (WRV), for instance. Mechanical pulp fibres are evidently more damaged than chemical pulp fibres which is seen as a much lower fibre strength (zero-span tensile strength). The reinforcement potential, on the grounds of fracture energy, tear strength and tensile strength of handsheets was much lower for mechanical pulp fibres than for chemical pulp. In the third trial, mechanical (MRP) and chemimechanical reinforcement pulp (CMRP) was manufactured from Norway spruce (P.abies) on a pilot scale. The focus was to increase fibre flexibility, bonding ability and maintain the fibre length and strength. The runnability of LWC base paper made from the trial pulps was tested using the KCL AHMA runnability tester. In spite of the good strength properties of the trial pulps, they did not have the same overall reinforcement ability than chemical pulp. The sulphonated trial pulp (CMRP) gave the same tensile stiffness and tensile strength as the chemical pulp. However, the fracture properties and extensibility of the paper was worse with it. The lower average length of the trial pulps did not explain the difference totally. Scaling the fibre length with the zero-span tensile strength improved the explanatory power essentially. It was concluded that the low fibre strength is the basic reason for the poorer reinforcement ability of mechanical pulps fibres over chemical ones. en
dc.format.extent Verkkokirja (7549 KB, 125 s.)
dc.format.mimetype application/pdf
dc.language.iso en en
dc.publisher Aalto University en
dc.relation.ispartofseries Aalto University publication series DOCTORAL DISSERTATIONS , 47/2011 en
dc.relation.haspart [Publication 1]: Lehto, J.H. 2003. Mechanical fibers as reinforcement pulp. 2003 International Paper Physics Conference. Victoria, B.C., Canada, 7-11 Sept. 2003, Montreal, Canada, PAPTAC, 323-331. © 2003 Pulp and Paper Technical Association of Canada (PAPTAC). By permission. en
dc.relation.haspart [Publication 2]: Lehto, J.H. 2004. Characterization of mechanical and chemical pulp fibers. 58th Appita annual conference and exhibition, Canberra, ACT, Australia, 19-21 April 2004, Carlton, VIC, Australia, Appita, Paper 3A13, 8 p. © 2003 Australian and New Zealand Pulp and Paper Industry Technical Association (Appita). By permission. en
dc.relation.haspart [Publication 3]: Lehto, J., Koskenhely, K., Paulapuro, H. 2007. The role of chemical and mechanical pulp fibres in LWC base paper. PTS pulp technology symposium, Dresden, Germany, 27-28 Nov. 2007, Munich, Germany, PTS, Paper 9, 17 p. © 2007 Papiertechnische Stiftung (PTS). By permission. en
dc.relation.haspart [Publication 4]: Lehto, J., Hiltunen, E., Paulapuro, H. 2010. TMP long fibres as reinforcement pulp. Part 1. Laboratory tests. Nord. Pulp Paper Res. J. 25(3), 328-339. © 2010 by authors. en
dc.relation.haspart [Publication 5]: Lehto, J., Hiltunen, E., Paulapuro, H. 2010. TMP long fibres as reinforcement pulp. Part 2. Pilot tests. Nord. Pulp Paper Res. J. 25(3), 340-350. © 2010 by authors. en
dc.subject.other Paper technology
dc.title Reinforcement ability of mechanical pulp fibres en
dc.type G5 Artikkeliväitöskirja fi
dc.contributor.school Kemian tekniikan korkeakoulu fi
dc.contributor.department Puunjalostustekniikan laitos fi
dc.contributor.department Department of Forest Products Technology en
dc.subject.keyword characterization en
dc.subject.keyword chemical pulp en
dc.subject.keyword mechanical pulp en
dc.subject.keyword refining en
dc.subject.keyword reinforcement ability en
dc.subject.keyword sulphonation en
dc.subject.keyword TMP en
dc.identifier.urn URN:ISBN:978-952-60-4143-8
dc.type.dcmitype text en
dc.type.ontasot Väitöskirja (artikkeli) fi
dc.type.ontasot Doctoral dissertation (article-based) en
dc.contributor.supervisor Paulapuro, Hannu, Prof. Emeritus


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