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2016 Vol.48, Issue 6 Preview Page
Effects of Pre-treatment by Betaine-Oxalic Acid Based Deep Eutectic Solvent on Manufacturing Efficiency of Microfibrillated Cellulose

베타인-옥살산 공융용매 전처리가 MFC 제조효율에 미치는 영향

Kyoung-Hwa Choi
,
Jae-Hoon Lee
,
Myoung-Ku Lee1
,
Jeong-Yong Ryu1
최경화
,
이재훈
,
이명구 1
,
류정용 1
Changgang Institute of Paper Science and Technology, Kangwon National University, Chunchon, 24341
1Dept. of Paper Science & Engineering, College of Forest and Environmental Sciences, Kangwon National University, Chunchon, 24341
강원대학교 창강제지기술연구소
1강원대학교 산림환경과학대학 제지공학과
E-mail: jyryu@kangwon.ac.kr
E-mail: mklee@kangwon.ac.kr
30 December 2016. pp. 203-210
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Abstract

This study was conducted to investigate the effects of deep eutectic solvent (DES) applied pre-treatment on the MFC manufacturing efficiency of hardwood bleached kraft pulp (HwBKP). DES was prepared by mixing of betaine and oxalic acid dihydrate (B and O), and the molar ratio of these two components mixtures was controlled to 1:1 (B:O=1:1). As results, grinding without BO DES pre-treatment shows the higher fiber fibrillation than that pre-treated with BO DES. And the energy that required to produce the MFC slurry having a same level of viscosity was slightly more consumped in case of BO DES pre-treatment than the case without pre-treatment. In other hand, the viscosity of the HwBKP fiber was decreased by BO DES pre-treatment but the viscosity of the HwBKP fiber treated with BO DES was less reduced by grinding than that without BO DES pre-treatment. Namely, it was found that BO DES pre-treatment diminished the cellulose degradation by grinding.

Keywords
Deep eutectic solvent
BO (betaine and oxalic acid dihydrate)
HwBKP (hardwood bleached kraft pulp)
fibrillation
energy consumption
cellulose degradation
References

Literature Cited

1
C. Salas, T. Nypelö, C. Rodriguez-Abreu, C. Carrillo and O. J. Rojas, Current Option in Colloid & Interface Science, Nanocellulose properties and applications in colloids and interfaces, 19(5); 383-396 (2014)

Salas, C., Nypelö, T., Rodriguez-Abreu, C., Carrillo, C., and Rojas, O. J., Nanocellulose properties and applications in colloids and interfaces, Current Option in Colloid & Interface Science 19(5):383-396 (2014).

10.1016/j.cocis.2014.10.003
2
M. Ankerfors, Microfibrillated cellulose: Energy-efficient preparation techniques and key properties ; 38, Stockholm, Sweden. TRITA-CHE Report, Royal Institute of Technology. (2012)

Ankerfors, M., Microfibrillated cellulose: Energy-efficient preparation techniques and key properties, TRITA-CHE Report, Royal Institute of Technology, Stockholm, Sweden, pp. 38 (2012).

3
T. Taniguchi and K. Okamura, Polymer International, New films produced from microfibrillated natural fibres, 47(3); 291-294 (1998)

Taniguchi, T. and Okamura, K., New films produced from microfibrillated natural fibres, Polymer International 47(3):291-294 (1998).

4
M. J. Cho and B. D. Park, Journal of the Korean Wood Science and Technology, Current research on nanocellulose-reinforced nanocomposites, 38(6); 587-601 (2010)

Cho, M. J. and Park, B. D., Current research on nanocellulose-reinforced nanocomposites, Journal of the Korean Wood Science and Technology 38(6):587-601 (2010).

10.5658/WOOD.2010.38.6.587
5
E. Loranger, A. O. Piche and C. Daneault, Nanomaterials, Influence of high-shear dispersion on the production of cellulose nanofibers by ultrasound-assisted TEMPO oxidation of kraft pulp , 2(3); 286-297 (2012)

Loranger, E., Piche, A. O., and Daneault, C., Influence of high-shear dispersion on the production of cellulose nanofibers by ultrasound-assisted TEMPO oxidation of kraft pulp, Nanomaterials 2(3):286-297 (2012).

10.3390/nano2030286
6
N. Siddiqui, R. H. Mills, D. J. Gardner and D. Bousfield, Journal of Adhesion Science and Technology, Production and characterization of cellulose nanofibers from wood pulp , 25(6-7); 709-721 (2011)

Siddiqui, N., Mills, R. H., Gardner, D. J., and Bousfield, D., Production and characterization of cellulose nanofibers from wood pulp, Journal of Adhesion Science and Technology 25(6-7):709-721 (2011).

10.1163/016942410X525975
7
I. Siró and D. Plackett, Cellulose, Microfibrillated cellulose and new nanocomposite materials: a review, 17(3); 459-494 (2010)

Siró, I. and Plackett, D., Microfibrillated cellulose and new nanocomposite materials: a review, Cellulose 17(3):459-494 (2010).

10.1007/s10570-010-9405-y
8
J. A. Sirviö, M. Visanko and H. Liimatainen, Green Chemistry, Deep eutectic solvent system based on choline chloride-urea as a pre-treatment for nanofibrillation of wood celllulose , 17(6); 3401-3406 (2015)

Sirviö, J. A., Visanko, M., and Liimatainen, H., Deep eutectic solvent system based on choline chloride-urea as a pre-treatment for nanofibrillation of wood celllulose, Green Chemistry 17(6):3401-3406 (2015).

10.1039/C5GC00398A
9
J. A. Sirviö, M. Visanko and H. Liimatainen, Biomacromolecules, Acidic deep eutectic solvents as hydrolytic media for cellulose nanocrystal production , 17(9); 3025-3032 (2016)

Sirviö, J. A., Visanko, M., and Liimatainen, H., Acidic deep eutectic solvents as hydrolytic media for cellulose nanocrystal production, Biomacromolecules 17(9):3025-3032 (2016).

10.1021/acs.biomac.6b00910
10
Y. Jin and K. H. Row, Korean Journal of Chemical Engineering, Adsorption isotherm of ibuprofen on molecular imprinted polymer, 22(2); 264-267 (2005)

Jin, Y. and Row, K. H., Adsorption isotherm of ibuprofen on molecular imprinted polymer, Korean Journal of Chemical Engineering 22(2):264-267 (2005).

10.1007/BF02701495
11
M. Francisco, M. Francisco, A. van den Bruinhorst and M. C. Kroon, Green Chemistry, New natural and renewable low transition temperature mixtures (LTTMs): Screening as solvents for lignocellulosic biomass processing , 14(8); 2153-2157 (2012)

Francisco, M., van den Bruinhorst, A., and Kroon, M. C., New natural and renewable low transition temperature mixtures (LTTMs): Screening as solvents for lignocellulosic biomass processing, Green Chemistry 14(8):2153-2157 (2012).

10.1039/c2gc35660k
12
M. C. Kroon, M. F. Casal and A. van den Bruinhorst, Pretreatment of lignocellulosic biomass and recovery of substituents using natural deep eutectic solvents/compound mixures with low transition temperatures (2014)

Kroon, M. C., Casal, M. F., and van den Bruinhorst, A., Pretreatment of lignocellulosic biomass and recovery of substituents using natural deep eutectic solvents/compound mixures with low transition temperatures, U.S. Patent Application No. 14/391,165 (2014).

13
A. K. Kumar, B. S. Parikh and M. Pravakar, Natural deep eutectic solvent mediated pretreatment of rice straw: Bioanalytical characterization of lignin extract and enzymatic hydrolysis of pretreated biomass residue , Environmental Science and Pollution Research. (2015)

Kumar, A. K., Parikh, B. S., and Pravakar, M., Natural deep eutectic solvent mediated pretreatment of rice straw: Bioanalytical characterization of lignin extract and enzymatic hydrolysis of pretreated biomass residue, Environmental Science and Pollution Research (2015).

14
P. Domínguez de María, Journal of Chemical Technology and Biotechnology, Recent trends in (ligno) cellulose dissolution using neoteric solvents: Switchable, distillable, and bio-based ionic liquids , 89(1); 11-18 (2014)

Domínguez de María, P., Recent trends in (ligno) cellulose dissolution using neoteric solvents: Switchable, distillable, and bio-based ionic liquids, Journal of Chemical Technology and Biotechnology 89(1):11-18 (2014).

10.1002/jctb.4201
15
Q. Zhang, M. Benoit, K. De Oliverial Vigier, J. Barrault and F. Jérôme, Chemistry-A European Journal, Green and inexpensive choline-derived solvent for cellulose decrystallization , 18(4); 1043-1046 (2012)

Zhang, Q., Benoit, M., De Oliverial Vigier, K., Barrault, J., and Jérôme, F., Green and inexpensive choline-derived solvent for cellulose decrystallization, Chemistry-A European Journal 18(4):1043-1046 (2012).

10.1002/chem.201103271
16
N. Tanaka, Y. Akamatsu, T. Hattori and M. Shimada, Wood Research, Effect of oxalic acid on the oxidative breakdown of cellulose by the fenton reaction , 81; 8-10 (1994)

Tanaka, N., Akamatsu, Y., Hattori, T., and Shimada, M., Effect of oxalic acid on the oxidative breakdown of cellulose by the fenton reaction, Wood Research 81:8-10 (1994).

17
M. Fišerová, E. Opálená and A. Illa, Wood Research, Hot water and oxalic acid pre-extraction of beech wood integrated with kraft pulping , 58(3); 381-394 (2013)

Fišerová, M., Opálená, E., and Illa, A., Hot water and oxalic acid pre-extraction of beech wood integrated with kraft pulping, Wood Research 58(3):381-394 (2013).

Information
  • Publisher :Korea Technical Association of The Pulp and Paper Industry
  • Publisher(Ko) :한국펄프종이공학회
  • Journal Title :Journal of Korea TAPPI
  • Journal Title(Ko) :펄프종이기술
  • Volume : 48
  • No :6
  • Pages :203-210
  • Received Date : 2016-11-17
  • Revised Date : 2016-12-16
  • Accepted Date : 2016-12-19
  • DOI :https://doi.org/10.7584/JKTAPPI.2016.12.48.6.203
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