Production of Nanofibrillated Cellulose by Mechanical Dissociation

被引：1

作者：

Koester, Alexander ^{[1
]}

Foerter-Barth, Ulrich ^{[1
]}

Herrmann, Michael ^{[1
]}

Schweppe, Rainer ^{[1
]}

Teipel, Ulrich ^{[1
,2
]}

机构：

[1] Fraunhofer Inst Chem Technol ICT, D-76327 Pfinztal, Germany

[2] Tech Hsch Nurnberg Georg Simon Ohm, D-90489 Nurnberg, Germany

来源：

CHEMIE INGENIEUR TECHNIK | 2014年 / 86卷 / 03期

关键词：

Cellulose; Mechanischer Aufschluss; Mikrofasern; Nanofasern; Mechanical dissociation; Microfibres; Nanofibres;

D O I：

10.1002/cite.201300128

中图分类号：

TQ [化学工业];

学科分类号：

0817 ;

摘要：

Mithilfe eines zweistufigen Verfahrens, bestehend aus der Dispergierung in Natronlauge und dem anschlie ss enden mechanischen Aufschluss in einer Ruhrwerkskugelmuhle, konnte ein Cellulosevlies in nanoskalige Fibrillen mit Durchmessern im Bereich von einigen nm bis etwa 30nm aufgeschlossen werden. Dies zeigen auch die Kristallstrukturanalysen, die mit einer tendenziell verfeinerten Kritallitgro ss e im Bereich der Fibrillendurchmesser auf den Aufschluss der Cellulose in Nanofibrillen hindeuten. Die Faserlange konnte dabei weitestgehend erhalten bleiben. Decomposition of a cellulose fleece in nanofibrils with diameters ranging from several nm to around 30nm could be realized by establishing a two-step process: the dispersion in sodium hydroxide solution followed by a mechanical dissociating step. This is supported by the crystal structure analysis, which indicates, with a refined crystallite size in the range of the fibril diameter, the decomposition of the cellulose in nanofibrils. The fiber length was largely preserved.

引用

页码：302 / 306

页数：5

共 50 条

[21] Influence of nanofibrillated cellulose on the mechanical and thermal properties of poly(lactic acid)
Peric, Matea
Putz, Robert
Paulik, Christian
EUROPEAN POLYMER JOURNAL, 2019, 114 : 426 - 433
[22] Mechanical and thermal properties of nanofibrillated cellulose reinforced silica aerogel composites
Wong, Joanna C. H.
Kaymak, Hicret
Tingaut, Philippe
Brunner, Samuel
Koebel, Matthias M.
MICROPOROUS AND MESOPOROUS MATERIALS, 2015, 217 : 150 - 158
[23] One-Step Production of Amphiphilic Nanofibrillated Cellulose Using a Cellulose-Producing Bacterium
Tajima, Kenji
Kusumoto, Ryo
Kose, Ryota
Kono, Hiroyuki
Matsushima, Tokuo
Isono, Takuya
Yamamoto, Takuya
Satoh, Toshifumi
BIOMACROMOLECULES, 2017, 18 (10) : 3432 - 3438
[24] EXAMINING THE EFFICIENCY OF MECHANIC/ENZYMATIC PRETREATMENTS IN MICRO/NANOFIBRILLATED CELLULOSE PRODUCTION
Tozluoglu, Ayhan
Poyraz, Bayram
Candan, Zeki
MADERAS-CIENCIA Y TECNOLOGIA, 2018, 20 (01): : 67 - 84
[25] Effect of homogenization (microfluidization) process parameters in mechanical production of micro- and nanofibrillated cellulose on its rheological and morphological properties
Taheri, Hesam
Samyn, Pieter
CELLULOSE, 2016, 23 (02) : 1221 - 1238
[26] Production and Characterization of Pulp and Nanofibrillated Cellulose from Selected Tropical Plants
Stanislas, Tido Tiwa
Tendo, Josepha Foba
Ojo, Emeso Beckley
Ngasoh, Odette Fayen
Onwualu, Peter Azikiwe
Njeugna, Ebenezer
Savastano Junior, Holmer
JOURNAL OF NATURAL FIBERS, 2022, 19 (05) : 1592 - 1608
[27] Production of Micro- and Nanofibrillated Cellulose through an Aqueous Counter Collision System Followed by Ultrasound: Effect of Mechanical Pretreatments
Tsalagkas, Dimitrios
Zhai, Lindong
Kafy, Abdullahil
Kim, Jung Woong
Kim, Hyun Chan
Kim, Jaehwan
JOURNAL OF NATURAL FIBERS, 2020, 17 (08) : 1099 - 1110
[28] Effect of homogenization (microfluidization) process parameters in mechanical production of micro- and nanofibrillated cellulose on its rheological and morphological properties
Hesam Taheri
Pieter Samyn
Cellulose, 2016, 23 : 1221 - 1238
[29] Multilayers of cellulose derivatives and chitosan on nanofibrillated cellulose
Junka, Karoliina
Sundman, Ola
Salmi, Jani
Osterberg, Monika
Laine, Janne
CARBOHYDRATE POLYMERS, 2014, 108 : 34 - 40
[30] Nanofibrillated cellulose: properties reinvestigated
Ali Naderi
Cellulose, 2017, 24 : 1933 - 1945

← 1 2 3 4 5 →