1 850
Cellulose (2025) 32:1835–1850
https://doi.org/10.15376/biores.14.3.
14:6370–6383.
slurry on high-vacuum dewatering: a laboratory study . Tappi J 78:140–147 Ramaswamy S (2003) Vacuum dewatering during pape r manufacturing. Drying Technol 21:685–717. https://doi. org/10.1081/drt-120019058 Rezk K, Nilsson L, Forsberg J, Berghel J (2013) Model- ling of water removal during a paper vacuum dewater- ing process using a level-set method. Chem Eng Sc i 101:543–553. https://doi.org/10.1016/j.ces.2013.07.005 Singh CK (1996) The effects of fines, drying intensity an d recycling on pulp and paper properties. Dissertation, Western Michigan University Sjöstrand B, Nilsson L, Ullsten H, Barbier C (2020) Numeri- cal model of water removal and air penetration durin g vacuum dewatering. Drying Technol 39:1349–1358. https://doi.org/10.1080/07373937.2020.1745825 Sjöstrand B, Barbier C, Ulkten H, Nilsson L (2019) Dewater- ing of softwood kraft pulp with additives of microfibril- lated cellulose and dialcohol cellulose. BioResources
6370-6383 Sjöstrand B (2017) Dewatering aspects at the forming section of the paper machine: rewetting and forming fabric struc- ture. Dissertation, Karlstad University Sjöstrand B (2020) Vacuum dewatering of cellulosic materials: new insights into transport phenomena in the papermak- ing process. Dissertation, Karlstad University Sundblad S (2015) Predictions of pulp and paper properties based on fiber morphology. Dissertation, KTH Royal Institute of Technology Publisher’s Note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Vol:. (1234567890)
Made with FlippingBook. PDF to flipbook with ease