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2019 Vol.51, Issue 3 Preview Page
Wet Strength Development of Cellulosic Materials via Caustic Treatment

염기처리에 의한 셀룰로오스 소재의 습윤강도 변화

Jung Soo Han
,
Yung Bum Seo
한정수
,
서영범
Department of Bio-based Materials, Chungnam National University, Daejeon, 34134
충남대학교 환경소재공학과
Corresponding author: E-Mail: ybseo@cnu.ac.kr
30 June 2019. pp. 59-67
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Abstract

Synthetic wet strength resins have been frequently used to develop the paper wet strength. Such resins may contain health-hazardous chemicals. Thus, we applied herein the caustic treatment process, in which a wet sheet of paper is immersed in a highly concentrated caustic solution for less than 1 h and then washed out. Consequently, high-aspect ratio fibers, such as red algae and abaca fibers, developed a much more wet strength than wet strength resin. However, wood fibers with a much less aspect ratio compared to abaca fibers developed almost no wet strength. Wood fiber refining helped increase the wet strength, but it was much less than wet strength resin. The mechanically prepared nanocellulose, which is a cellulose fibril collection, effectively developed wet strength via alkaline treatment. This technology can be applied when wet strength is needed without hazardous chemicals.

Keywords
Wet strength
caustic treatment
fiber-fiber entanglement
Nanocellulose
aspect ratio
References

Literature Cited

1
N. Dunlop-Jones and J. C. Roberts, 2nd Edition. In Paper ChemistryWet-strength chemistry; 76-94, London, UK. Blackie, Chapman & Hall. (1996)

Dunlop-Jones, N., Wet-strength chemistry, In Paper Chemistry 2nd Edition, Roberts, J. C. (ed.) pp. 76-94, Blackie, Chapman & Hall, London, UK (1996).

2
T. Lindström, L. Wågberg and T. Larsson, On the nature of joint strength in paper- A review of dry and wet strength resins used in paper manufacturingSession 3, Part I, 13th Fundamental Research Symposium, Cambridge: UK (2005)

Lindström, T., Wågberg, L., and Larsson, T., On the nature of joint strength in paper- A review of dry and wet strength resins used in paper manufacturing, Session 3, Part I, 13th Fundamental Research Symposium, Cambridge: UK (2005).

3
T. Saito and A. Isogai, Industrial & Engineering Chemistry Research, Wet strength improvement of TEMPO-oxidized cellulose sheets prepared with cationic polymers, 46(3); 773-780 (2007)

Saito, T. and Isogai, A., Wet strength improvement of TEMPO-oxidized cellulose sheets prepared with cationic polymers, Industrial & Engineering Chemistry Research 46(3):773-780 (2007).

10.1021/ie0611608
4
B. Sun, Q. Hou, Z. Liu and Y. Ni, Cellulose, Sodium periodate oxidation of cellulose nanocrystal and its application as a paper wet strength additive, 22(2); 1135-1146 (2015)

Sun, B., Hou, Q., Liu, Z., and Ni, Y., Sodium periodate oxidation of cellulose nanocrystal and its application as a paper wet strength additive, Cellulose 22(2):1135-1146 (2015).

10.1007/s10570-015-0575-5
5
K. Abe and H. Yano, Cellulose, Cellulose nanofiber-based hydrogels with high mechanical strength, 19(6); 1907-1912 (2012)

Abe, K. and Yano, H., Cellulose nanofiber-based hydrogels with high mechanical strength, Cellulose 19(6):1907-1912 (2012).

10.1007/s10570-012-9784-3
6
T. Nakano, Cellulose, Mechanism of microfibril contraction and anisotropic dimensional changes for cells in wood treated with aqueous NaOH solution, 17(4); 711-719 (2010)

Nakano T., Mechanism of microfibril contraction and anisotropic dimensional changes for cells in wood treated with aqueous NaOH solution, Cellulose 17(4):711-719 (2010).

10.1007/s10570-010-9414-x
7
Y. B. Seo, Y. W. Lee, C. H. Lee and H. C. You, Bioresources Technology, Red algae and their use in papermaking, 101; 2549-2553 (2010)

Seo, Y. B., Lee, Y. W., Lee, C. H., and You, H. C., Red algae and their use in papermaking, Bioresources Technology 101:2549-2553 (2010).

10.1016/j.biortech.2009.11.088
8
J. E. Atchison, 3rd ed.. In Pulp and Paper ManufactureData on non-wood plant fibers, 3; 11, (Secondary fibers and non-wood pulping), USA and Canada. The Joint Textbook Committee of the Paper Industry, TAPPI and CPPA. (1987)

Atchison, J. E., Data on non-wood plant fibers, In Pulp and Paper Manufacture 3rd ed., Vol. 3 (Secondary fibers and non-wood pulping), p. 11, The Joint Textbook Committee of the Paper Industry, TAPPI and CPPA, USA and Canada (1987).

9
S. Varanasi, R. He and W. Batchelor, Cellulose, Estimation of cellulose nanofibre aspect ratio from measurements of fibre suspension gel point, 20(4); 1885-1896 (2013)

Varanasi, S., He, R., and Batchelor, W., Estimation of cellulose nanofibre aspect ratio from measurements of fibre suspension gel point, Cellulose 20(4):1885-1896 (2013).

10.1007/s10570-013-9972-9
10
N. Amiralian, P. K. Annamalai, C. J. Garvey, E. Jiang, P. and Memmott and D. J. Martin, Cellulose, High aspect ratio nanocellulose from an extremophile spinifex grass by controlled acid hydrolysis, 24; 3753-3766 (2017)

Amiralian, N., Annamalai, P. K., Garvey, C. J., Jiang, E., and Memmott, P., and Martin, D. J., High aspect ratio nanocellulose from an extremophile spinifex grass by controlled acid hydrolysis, Cellulose 24:3753-3766 (2017).

10.1007/s10570-017-1379-6
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 : 51
  • No :3
  • Pages :59-67
  • Received Date : 2019-05-20
  • Revised Date : 2019-06-11
  • Accepted Date : 2019-06-14
  • DOI :https://doi.org/10.7584/JKTAPPI.2019.06.51.3.59
Journal Informaiton Journal of Korea TAPPI Journal of Korea TAPPI
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