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2020 Vol.52, Issue 6 Preview Page
Effects of Pulp Type and Stock Concentration on Foamability and Bubble Size of Fiber Foam

펄프 종류와 지료 농도가 섬유 거품의 발포성과 기포 크기에 미치는 영향

Min-a Park1
,
Se-young Oh1
,
Chi-hyun Ahn1
,
Myung-Jun Park1
,
Byoung-Uk Cho2
박민아 1
,
오세영 1
,
안치현 1
,
박명준 1
,
조병욱 2
1Dept. of Paper Science & Engineering, College of Forest and Environmental Sciences, Kangwon National University
2Dept. of Paper Science & Engineering, College of Forest and Environmental Sciences, Kangwon National University
1강원대학교 산림환경과학대학 제지공학과, 학생
2강원대학교 산림환경과학대학 제지공학과, 교수
Corresponding author: E-Mail: bucho@kangwon.ac.kr (Address: Dept. of Paper Science & Engineering, College of Forest and Environmental Sciences, Kangwon National University, Chunchon, Republic of Korea)
30 December 2020. pp. 123-131
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Abstract

Effects of pulp type and pulp concentration on foamability and bubble size of fiber foam were investigated as fundamental research to develop foam forming technology. Two types of chemical pulps, a mechanical pulp, and a recycled pulp were utilized. In addition, sodium dodecyl sulfate was used as surfactant to improve foamability. It was found that 0.5 g/L of surfactant and 1-2 minutes of mixing at 3,500 rpm were enough to produce foam with more than 60% of air content. The foamability of HwBKP suspension showed the lowest value while OCC (old corrugated container, recycled pulp) stock has the highest foamability. OCC foam and CTMP foam had more bubbles with smaller sizes while HwBKP foam consisted of bigger size bubbles. The increase of pulp concentration reduced foamability and decreased average bubble size in foam while the increase of SDS addition improved foamability and decreased bubble size.

Keywords
Foam foaming
foamability
bubble size
pulp type
pulp concentration
surfactant concentration
References

Literature Cited

1

Jahangiri, P., Novel cellulose based foam-formed products: Applications and numerical studies, Master’s Thesis, University of British Columbia, Canada (2013).

2

Radvan, B. and Gatward, A. P. J., The formation of wet-laid webs by a forming process, Tappi Journal 55(5):748:751 (1972).

3

Smith, M. K. and Punton, V. W., The role of the forming process in determining the structure and properties of paper, Pulp & Paper Canada 76(2):114-117 (1975).

4

Smith, M. K., Punton, V. W., and Rixon, A. G., The structure and properties of paper formed by a foaming process, Tappi Journal 57(1):107-111 (1974).

5

Lehmonen, J., Jetsu, P., Kinnunen, K., and Hjelt, T., Potential of foam-laid forming technology in paper applications, Nordic Pulp & Paper Research Journal 28(3):392-398 (2013).

10.3183/npprj-2013-28-03-p392-398
6

Torvinen, K., Lahtinen, P., Kiiskinen, H., Hellen, E., and Koponen, A., Bulky paper and board at high dry solids content with foam forming, In: Proceedings of Papercon 2015, Atalanta, Georgia, USA, pp.757-766 (2015).

7

Tringham, R. W. and Manager, M. A., New developments in Radfoam process, Paper Technology 15(5):288-294 (1974).

8

Punton, V., Fiber distribution in foam and foam-laid paper, In: International Paper Physics Conference, p.135-139 (1975).

9

Koponen, A., Torvinen, K., Jaäsberg, A., and Kiiskinen, H., Foam forming of long fibers, Nordic Pulp & Paper Research Journal 31(2):239-247 (2016).

10.3183/npprj-2016-31-02-p239-247
10

Madani, A., Zeinoddini, S., Varahmi, S., Turnbull, H., Phillion, A. B., Olson, J. A., and Martinez, D. M., Ultra-lightweight paper foams: Processing and properties, Cellulose 21:2023-2031 (2014).

10.1007/s10570-014-0197-3
11

Alimadadi, M., Foam-formed fiber networks: Manufacturing, characterization, and numerical modeling, Ph.D. Thesis, Mid Sweden University, Sundsvall, Sweden (2018).

12

Hellen, E., Jetsu, P., and Lehmonen, J., Foam forming – What could it mean for tissue?, Paper Technology 54(4):10-12 (2013).

13

Al-Qararah, A. M., Aqueous foam as the carrier phase in the deposition of fibre networks, Ph.D. Thesis, University of Jyväskylä, Finland (2015).

14

Al-Qararah, A. M., Ekman, A., Hjelt, T., Ketoja, J. A., Kiiskinen, H., Koponen, A., and Timonen, J., A unique microstructure of the fiber networks deposited from-fiber suspensions, Colloids and Surfaces A 482:544-553 (2015).

10.1016/j.colsurfa.2015.07.010
15

Al-Qararah, A. M., Hjelt, T., Kinnunen, K., Beletski, N., and Ketoja, J. A., Exceptioal pore size distribution in foam-formed fibre networks, Nordic Pulp & Paper Research Journal 27(2):226-230 (2012).

10.3183/npprj-2012-27-02-p226-230
16

Mira, I., Andersson, M., Boge, L., Blute, I., Carlsson, G., Salminen, K., Lappalainen, T., and Kinnunen, K., Foam forming revisted, Part I. Foaming behavior of fibre-surfactant systems, Nordic Pulp & Paper Research Journal 29(4):679-689 (2014).

10.3183/npprj-2014-29-04-p679-689
17

Kinnunen, K., Lehmonen, J., Beletski, N., Jetsu, P., and Hjelt, T., Benefits of foam forming technology and its applicability in high MFC addition structures, 15th Fundamental Research Symposium, Cambridge, pp.837-850 (2013).

18

Jasberg, A., Selenius, P., and Koponen, A., The effect of fibrous materials on the rheology of aqueous foams, 16th Fundamental Research Symposium, Oxdord, UK, pp.159-173 (2017).

19

Poranen, J., Kiiskinen, H., Salmela, J., Asikainen, J., Keränen, J. T., and Pääkkonen, E.,, Breaking through in papermakng resource efficieny with foam forming, Proceeding of Paper Conference and Trade Show, PaperCon 2013, Atlanta, USA, vol. 1, pp.807-814 (2013).

20

Park, S. Y., Goo, S., Yook, S., and Youn, H. J., Characteristics of cellulose nanofibrils-stabilized wet foam depending on the addition level of surfactant, Journal of Korea TAPPI 51(6):128-134 (2019).

10.7584/JKTAPPI.2019.12.51.6.128
21

Lappalainen, T. and Lehmonen, J., Determinations of bubble size distribution of foam-fibre mixture using circular hough transform, Nordic Pulp & Paper Research Journal 27(5):930-939 (2012).

10.3183/npprj-2012-27-05-p930-939
22

Lappalainen, T., Salminen, K., Kinnunen, K., Järvinen, M., Mira, I., and Andersson, M., Foam forming revisited. Part II. Effect of surfactant on the properties of foam-formed paper products, Nordic Pulp & Paper Research Journal 29(4):689-699 (2014).

10.3183/npprj-2014-29-04-p689-699
23

Kiiskinen, H., Salminen, K., Lappalainen, T., Asikainen, J., Keranen, J., and Hellen, E., Progess in foam forming technology, Tappi Journal 18(8):499-510 (2019).

10.32964/TJ18.8.499
24

Saint-Jalmes, A., Physical chemistry in foam drainage and coarsening, Soft Matter 2(10):836-849 (2006).

10.1039/b606780h
25

Engelsen, C. W., Isarin, J. C., Gooijer, H., Warmoeskerken, M., and Wassink, J. G., Bubble size distribution of foam, AUTEX Research Journal 2(1):14-27 (2002).

26

Al-Qararah, A. M., Hjelt, T., Koponen, A., Harlin, A., and Ketoja, J. A., Bubble size and air content of wet fibre foams in axial mixing with macro-instabilities, Colloids and Surfaces A. 436(5):1130-1139 (2013).

10.1016/j.colsurfa.2013.08.051
27

Koponen, A., Jasberg, A., Lappalainen, T,. and Kiiskinen, H., The effect of in-line foam generation on foam quality and sheet formation in foam forming, Nordic Pulp & Paper Research Journal 33(3):482-495 (2018).

10.1515/npprj-2018-3051
28

Stubenrauch, C., Shrestha, L. K., Varade, D., Johansson, I., Olanya, G., Aramaki, K., and Claesson, P., Aqueous foams stabilized by n-dodecyl-b-D-maltoside, hexaethyleneglycol monododecyl ether, and their 1:1 mixture, Soft Matter 5(16):3070-3080 (2009).

10.1039/b903125a
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 : 52
  • No :6
  • Pages :123-131
  • Received Date : 2020-12-02
  • Revised Date : 2020-12-16
  • Accepted Date : 2020-12-18
  • DOI :https://doi.org/10.7584/JKTAPPI.2020.12.52.6.123
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