Cellulose (2016) 23:2249–2272
2269
pulps determined by ESCA and AFM. Colloids Surf A 228:143–158 Koskenhely K, Robinson D, Weckroth R (2011) Neue Anwen- dungen fu¨r Mahlgarnituren mit feinem Messer- und Nutenprofil. Wochenblatt fu¨r Pap 139:103–106 Kouko J, Salminen K, Kurki M (2007) Laboratory scale mea- surement procedure of paper machine wet web runnability: part 2. Pap Puu 89:424–430 Kouko J, Retulainen E, Kekko P (2014) Straining and relaxation properties of wet paper during heating. Mech Time Depend Mater 18:697–719. doi:10.1007/s11043-014-9246-4 Kulachenko A, Uesaka T (2010) Simulation of wet fibre net- work deformation. In: Progress in Paper Physics, Montreal, Canada, 2010. FPInnovations Kurki M, Vestola J, Martikainen P, Pakarinen P (1997) The effect of web rheology and peeling on web transfer in open draw. In: 4th International Conference of Web Handling, pp 527–543 Kurki M, Kekko P, Kouko J, Saari T (2004) Laboratory scale measurement procedure of paper machine wet web runnability. Part 1. Pap Timber (Pap ja puu) 86:256–262 Laitinen O, Joensuu I, Niskanen T, Niinima¨ki J (2014) Analysis of the external fibrillation. IPW 68:46–52 Laivins GV, Scallan AM (1993) The mechanism of hornifica- tion of wood pulps. In: Baker CF (ed) Products of paper- making—Xth fundamental research symposium, vol 2., 10th Fundamental Research Symposium Pira, Oxford, pp 1235–1260 Laleg M, Pikulik II (1991) Web Strength increase by a cationic aldehyde starch. Paper presented at the Tappi Papermakers conference Laleg M, Pikulik II (1992) Strengthening of mechanical pulp webs by chitosan. Nord Pulp Pap Res J 7(174–180):199. doi:10.3183/NPPRJ-1992-07-04-p174-180 Laleg M, Pikulik II (1993a) Modified starches for increasing paper strength. J Pulp Pap Sci 19:J248–J255 Laleg M, Pikulik II (1993b) Unconventional strength additives. Nord Pulp Paper Res J 8:41–47 Laleg M, Pikulik II, Ono H, Barbe M, Seth R (1991) Paper strength increase by a cationic starch and a cationic alde- hyde starch. Paper presented at the PAPRICAN 88th annual meeting, Montreal, Canada Lappalainen T, Kouko J (2011) Determination of local strains and breaking behaviour of wet paper using a high-speed camera. Nord Pulp Pap Res J 26:288–298 Latil P, Orge´as L, Geindreau C, Dumont P, du Roscoat SR (2010) Towards the 3D in situ characterisation of defor- mation micro-mechanisms within a compressed bundle of fibres. Compos Sci Technol 71:480–488 Leporatti S et al (2005) Interaction forces between cellulose microspheres and ultrathin cellulose films monitored by col- loidal probe microscopy—effect of wet strenght agents. J Col- loid Interface Sci 281:101–111. doi:10.1016/j.jcis.2004.08.047 Lindqvist H (2013) Improvement of wet and dry web properties in papermaking by controlling water and fiber quality. Abo Akademi University, Turku Lindqvist H, Salminen K, Kataja-aho J, Sundberg A, Holmbom B, Retulainen E (2009) Effect of electrolytes, pH and surface tension on dry and wet web properties. J Pulp Pap Sci 35:148–154
Lindqvist H, Salminen K, Kataja-aho J, Retulainen E, Fardim P, Sundberg A (2011) Effect of fines on dewatering, wet and dry web properties. Paper presented at the PaperCon 2011, Cincinnati, USA Lindqvist H, Salminen K, Kataja-aho J, Retulainen E, Fardim P, Sundberg A (2012) The effect of fibre properties, fines content and surfactant addition on dewatering, wet and dry web properties. Nord Pulp Pap Res J 27:104–111 Lindqvist H, Holmback J, Rosling A, Salminen K, Holmbom B, Auer M, Sundberg A (2013) Galactoglucomannan deriva- tives and their application in papermaking. BioResources 8:994–1010 Lindstro¨m T (1980) Effect of chemical factors on fiber swelling and paper strength. Das Pap 34:561–568 Lindstro¨m T (1986) The porous lamellar structure of the cell wall. In: Bristow JA, Kolseth P (eds) Paper, structure and properties, vol 8., International Fiber Science and Tech- nology Series Marcel Dekker, New York, pp 99–109 Lindstro¨m T, Carlsson G (1982) The effect of carboxyl groups and their ionic form during drying on the hornification of cellulose fibers [pH, paper properties, tensile strength, swelling]. Svensk Papperstidning 85 Lindstro¨m T, Kolman M (1982) Effect of pH and electrolyte concentration during beating and sheet forming on paper strength. Svensk Papp 85:R140–R145 Lindstro¨m T, Wa˚gberg L, Larsson T (2005) On the nature of joint strength in paper—a review of dry and wet strength resins used in paper manufacturing. Paper presented at the Advances in Paper Science and Tech- nology—13th fundamental research symposium, Cam- bridge, UK Linhart F (2005) Some thoughts on the mode of action of paper strength agents. Wochenbl fu¨r Pap 133:662–672 Linhart F, Horn D, Eisenlauer J, Hemel R (1987) Monitoring and control of formation by means of a fiber optic floccu- lation sensor. Wochenbl Pap 115:331–338 Lobben T (1976) Tensile stiffness of paper. Part 2. Activation studied by freeze drying. Nor Skogindustri 30:43–48 Lobosco V (2004) On the modelling of mechanical dewatering in papermaking. PhD Thesis, Royal Institute of Technology Lyne LM, Gallay W (1954a) Fiber properties and fiber-water relationships in relation to the strength and rheology of the wet webs. TAPPI 37:581–596 Lyne LM, Gallay W (1954b) Studies in the fundamentals of wet web strength. TAPPI 37:698–704 Malhaire C et al (2009) Experimental setup and realization of thin film specimens for microtensile tests. Rev Sci Instrum. doi:10.1063/1.3077153 Maloney TC, Li TQ, Weise U, Paulapuro H (1997) Intra-and inter-fibre pore closure in wet pressing. Appita J 50: 301–306 Mardon J (1961) The release of wet paper webs from various ‘‘papermaking surfaces’’. Appita J 15:14–34 Mardon J (1976) Theoretical and experimental investigations into peeling of paper webs from solid-surfaces. Pap Ja Puu- Pap Timber 58:797–815 Marulier C, Dumont PJJ, Orgeas L, Caillerie D, Rolland Du Roscoat S (2012) Towards 3D analysis of pulp fibre net- works at the fibre and bond levels. Nord Pulp Pap Res J 27:245–255
123
Made with FlippingBook Digital Proposal Creator