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European Journal of Wood and Wood Products

, Volume 74, Issue 1, pp 57–65 | Cite as

Manufacture and properties of citric acid-bonded particleboard made from bamboo materials

  • Ragil WidyoriniEmail author
  • Kenji Umemura
  • Ramadhanu Isnan
  • Dian Rahma Putra
  • Ali Awaludin
  • Tibertius Agus Prayitno
Original

Abstract

Utilization of citric acid as natural binder for non-wood composite is still limited. Therefore, this study investigated the physical and mechanical properties of particleboard made from bamboo using citric acid as natural binder. Three bamboo particles, i.e. petung bamboo (Dendrocalamus asper), wulung bamboo (Gigantochloa atroviolacea), and apus bamboo (Gigantochloa apus) were used as raw materials in this research. Citric acid contents were set at 0, 15 and 30 wt.% based on air-dried particles. Two classifications of petung bamboo particle sizes (coarse and fine particles) were used in this research. The particleboards were also made as single layer and three layer boards with variation of layer compositions. The results showed that addition of citric acid could significantly improve the dimensional stability and mechanical properties of the boards, while bamboo species did not significantly affect the properties of boards. Fine particles provided higher internal bond strength of the particleboard than coarse particles, due to bigger contact area among fine particles. Single layer particleboard provided higher internal bond strength compared to the three layer ones. The properties of citric acid-bonded bamboo particleboard in this research could meet the requirements of the Japanese Industrial Standard for particleboard (A 5908). Fourier transform infrared analysis indicated that the peak at around 1734 cm−1 was hardly recognized in binderless board, however it clearly appeared in citric acid-bonded particleboards. As a result of reaction between citric acid and bamboo, good properties of particleboards could be obtained.

Keywords

Citric Acid Coarse Particle Resin Content Bamboo Species Thickness Swell 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.

Notes

Acknowledgments

The authors are grateful to Directorate General of Higher Education Ministry of National Education Indonesia and Universitas Gadjah Mada (Research Grant No. LPPM-UGM/1379/LIT/2013 and LPPM-UGM/462/LIT/2014). The authors also thank the student Ari Puspa Yudha for her assistance in fabrication of the composite.

References

  1. Bamboo Phylogeny Group (2012) An updated tribal and subtribal classification of the bamboos (Poaceae: Bambusoideae). Bamboo Sci Cult J Am Bamboo Soc 24(1):1–10Google Scholar
  2. Ghosh P, Das D, Samanta AK (1995) Modification of jute with citric acid. J Polym Mater 12:297–305Google Scholar
  3. Hasan M, Despot R, Jug M (2007) Modification of wood with citric acid for increasing biological durability of wood. In: Proceedings international symposium new technologies and materials in industries based on the forestry sector, pp 85–89Google Scholar
  4. Hiziroglu S, Suzuki S (2007) Evaluation of surface roughness of commercially manufactured particleboard and medium density fiberboard in Japan. J Mater Process Technol 184:436–440CrossRefGoogle Scholar
  5. Hiziroglu S, Jarusombuti S, Fueangvivat V (2004) Surface characteristic of wood composite manufactured in Thailand. Build Environ 39:1359–1364CrossRefGoogle Scholar
  6. Japanese Industrial Standard (2003) JIS A 5908-2003 particleboards. Japanese Standard Association, TokyoGoogle Scholar
  7. Nemli G, Ozturk I, Aydin A (2005) Some of parameters influencing surface roughness of particleboard. Build Environ 40:1337–1340CrossRefGoogle Scholar
  8. Okuda N, Sato M (2004) Manufacture and mechanical properties of binderless boards from kenaf core. J Wood Sci 50:53–61CrossRefGoogle Scholar
  9. Reddy N, Yang Y (2010) Citric acid cross-linking of strach films. Fodd Chem 118:702–711CrossRefGoogle Scholar
  10. Rowell RM (1991) Chemical modification of wood. In: Hon DN, Shiraishi N (eds) Wood and cellulosic chemistry. Marcel Dekker Inc., New York, pp 703–756Google Scholar
  11. Sackey EK, Semple KE, Oh SW, Smith GD (2008) Improving core bond strength of particleboard through particle size redistribution. Wood Fiber Sci 40:214–224Google Scholar
  12. Thanh ND, Nhung HL (2009) Cellulose modified with citric acid and its absorption of PB2+ and Cd2+ ions. In: Proceedings of the 13rd international electronic on synthetic organic chemistry (ECSOC-13)Google Scholar
  13. Umemura K, Ueda T, Munawar SS, Kawai S (2011) Application of citric acid as natural adhesive for wood. J Appl Polym Sci 123(4):1991–1996CrossRefGoogle Scholar
  14. Umemura K, Ueda T, Kawai S (2012a) Characterization of wood-based molding bonded with citric acid. J Wood Sci 58(1):38–45CrossRefGoogle Scholar
  15. Umemura K, Ueda T, Kawai S (2012b) Effect of moulding temperature on the physical properties of wood-based moulding bonded with citric acid. For Prod J 62(1):63–68Google Scholar
  16. Vancai L (2010) Physical and Mechanical Properties of Particleboard from Bamboo Waste. World Academy of Science, Engineering and Technology 40:566–570Google Scholar
  17. Vukusic SB, Katovic D, Schramm C, Trajkovic J, Sefc B (2006) Polycarboxylic acids as non-formaldehyde anti-swelling agents for wood. Holzforschung 60:439–444Google Scholar
  18. Widyorini R, Xu J, Watanabe T, Kawai S (2005) Chemical changes in steam-pressed kenaf core binderless particleboard. J Wood Sci 51:26–32CrossRefGoogle Scholar
  19. Widyorini R, Yudha AP, Prayitno TA (2011) Some of the properties of binderless particleboard manufactured from bamboo. Wood Res J 2(2):89–93Google Scholar
  20. Widyorini R, Yudha AP, Adifandi Y, Umemura K, Kawai S (2013) Characteristic of bamboo particleboard bonded using citric acid. Wood Res J 4(1):31–35Google Scholar
  21. Widyorini R, Yudha AP, Isnan R, Awaludin A, Prayitno TA, Ngadianto A, Umemura K (2014) Improving the physico-mechanical properties of eco-friendly composite made from bamboo. Adv Mater Res 896:562–565CrossRefGoogle Scholar
  22. Yang CQ, Xu Y, Wang D (1996) FT-IR spectroscopy study of the polycarboxylic acids used for paper wet strength improvement. Ind Eng Chem Res 35:4037–4042CrossRefGoogle Scholar
  23. Yu J, Wang N, Ma X (2005) The effects of citric acid on the properties of thermoplastic starch plasticized by glycerol. Starch/Starke 57:494–504CrossRefGoogle Scholar

Copyright information

© Springer-Verlag Berlin Heidelberg 2015

Authors and Affiliations

  • Ragil Widyorini
    • 1
    Email author
  • Kenji Umemura
    • 2
  • Ramadhanu Isnan
    • 1
  • Dian Rahma Putra
    • 1
  • Ali Awaludin
    • 3
  • Tibertius Agus Prayitno
    • 1
  1. 1.Forest Product Technology Department, Faculty of ForestryUniversitas Gadjah MadaYogyakartaIndonesia
  2. 2.Research Institute for Sustainable HumanosphereKyoto UniversityKyotoJapan
  3. 3.Faculty of EngineeringUniversitas Gadjah MadaYogyakartaIndonesia

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