Abstract
Abstract High yield pulps (HYP), manufactured in mechanical and chemimechanical pulping processes, are mainly used in graphic papers and paper grades where a high bulk is preferable, like in paperboards. Moreover, packaging papers with very high demands on both dry and wet strength could be manufactured from HYP in a near future. Preferred bonds between fibre components (long fibres, shortened fibres and fines) in the various paper grades are quite different. In the review, plausible effects of mechanical interlocking, intermolecular interactions (“physical bonding”), hydrogen bonds, intermixing of polymers, additives and possible specific interactions in the formation of strong bonds in sheet structures from HYP are discussed. A required condition for high bond strength in sheets from HYP furnishes is that fibre components are forced into sufficiently close contact. This is to a great extent impeded if the fibre walls are too stiff. Consequently, the current review focuses on both how fibre fractions should preferably be developed for different end uses and how suitable bonds might be achieved in different paper grades. The ideal type of bonds is certainly different depending on the demands on the final paper quality.
Highlights
High yield pulps (HYP), which are manufactured in stone groundwood (SGW), pressure groundwood (PGW), thermomechanical (TMP) and chemithermomechanical (CTMP) processes or variants of these, contain a mixture of wood fibres with their natural length, shortened fibres, fibre fragments and fines from outer parts of the fibre walls
Recent research has shown that packaging papers with very high demands on both dry and wet strength could be manufactured from HYP in a near future
Results similar to Figure are shown in investigations by Lindholm, Figure. He showed that the strength of sheets from TMP long-fibres fraction is somewhat lower than that of sheets from SGW and PGW
Summary
High yield pulps (HYP), which are manufactured in stone groundwood (SGW), pressure groundwood (PGW), thermomechanical (TMP) and chemithermomechanical (CTMP) processes or variants of these, contain a mixture of wood fibres with their natural length, shortened fibres, fibre fragments and fines from outer parts of the fibre walls. The interaction between long fibre and fines to create sheet structures of high strength in graphic papers will be discussed next.
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