생분해성 지방족 폴리부틸렌 석시네이트 수지를 이용한 자망과 통발용 단일섬유의 방사기술 개발 및 물리적 특성

Development and physical properties on the monofilament for gill nets and traps using biodegradable aliphatic polybutylene succinate resin

  • 박성욱 (국립수산과학원 수산공학팀) ;
  • 배재현 (국립수산과학원 수산공학팀) ;
  • 임지현 (국립수산과학원 수산공학팀) ;
  • 차봉진 (국립수산과학원 수산공학팀) ;
  • 박창두 (국립수산과학원 서해수산연구소 어업자원팀) ;
  • 양용수 (국립수산과학원 수산공학팀) ;
  • 안희춘 (국립수산과학원 수산공학팀)
  • Park, Seong-Wook (Fisheries Engineering Team, National Fisheries Research & Development Institute) ;
  • Bae, Jae-Hyun (Fisheries Engineering Team, National Fisheries Research & Development Institute) ;
  • Lim, Ji-Hyun (Fisheries Engineering Team, National Fisheries Research & Development Institute) ;
  • Cha, Bong-Jin (Fisheries Engineering Team, National Fisheries Research & Development Institute) ;
  • Park, Chang-Doo (Fisheries Resources Team, West Sea Fisheries Research Institute, NFRDI) ;
  • Yang, Yong-Su (Fisheries Engineering Team, National Fisheries Research & Development Institute) ;
  • Ahn, Heui-Chun (Fisheries Engineering Team, National Fisheries Research & Development Institute)
  • 발행 : 2007.11.30


This study was aimed not only to develop the gill net and trap made of biodegradable monofilaments in order to prevent a ghost fishing and to protect marine ecosystem, but also to analyze their spinning process and physical properties. Results showed that the spinning speed of biodegradable polybutylene succinate(PBS) monofilament was estimated to be approximately 100m/min when spinning temperature and cooling water temperature were adjusted at $180^{\circ}C$ and $3^{\circ}C$, respectively. The breaking loads of PBS monofilaments were estimated to be $35.3kg/mm^2$ at ${\phi}0.2mm$, $46.5kg/mm^2$ at ${\phi}0.3mm$, and $49.7kg/mm^2$ at ${\phi}0.4mm$ in the dry condition, respectively. However, its breaking loads in the wet condition were reduced by 2.4-5.5%, compared to those in the dry condition. The knotted strength of PBS monofilament at ${\phi}0.2mm$ was estimated to be 98.6% of PE in the dry condition. The breaking load of PBS monofilament at ${\phi}0.3mm$ was evaluated to be 81.8% of PA, and its softness showed 3 times less than that of PA in the wet condition. The breaking load of PBS monofilament at ${\phi}0.4mm$ was 95.3% of PA, and its softness showed 1.6 times less than that of PA in the wet state. However, the load elastic elongations of two kinds of monofilaments were estimated to be 1% higher than that of PA.


  1. Ayaz, A., D. Acarli, U. Altinagac, U. Ozekinci, A. Kara and A. Ozen, 2006. Ghost fishing by monofilament and multifilament gillnets in izmir bay, Turkey. Fisheries Research, 79, 267-271
  2. Bikiaris, D.M., G.Z. Papargiou, D.S. Achilias, E. Pavliodou and A. Stergiou, 2007. Miscibility and enzymatic degradation studies of poly(e- caprolactone)/poly(propylene succinate)blends. Europen Polymer Journal, article in press, 1-13
  3. Brown, J. and G. Macfadyen, 2007. Ghost fishing in European waters : impacts and management responses. Marine Policy, 31, 488-504
  4. Cao, A., T. Okamura, K. Nakayama, Y. Inoue and T. Masuda, 2002. Studies on syntheses and physical properties of biodegradable aliphatic poly(butylene succinate-co-ethylene succinate)s and poly(butylene succinateco-diethylene glycol succinate)s. Polymer Degradation and Stability, 78, 107-117
  5. Chrissafis K., K.M. Paraskevopoulos and D. N. Bikiaris, 2005. Thermal degradation mechanism of poly(ethylene succinate) and poly(butylene succinate): comparative study. Thermochimica acta, 435, 142-150
  6. Jin, H.J., B.Y. Lee, M.N. Kim and J.S. Yoon, 2000. Properties and biodegradation of poly(ethylene adipate) and poly((butylene succinate) containing styrene glycol units. European Polymer Journal, 36, 2693-2698
  7. Kang, H.J., T.W. Park, Y.J. Kim and Y.,R. Lee, 1996. Biodegradable aliphatic polyester(I), synthesis and physical ptoperties of coplyesterethylene. Korean Polymer, 22(4), 682-690
  8. Kim, D.A. and K.S. Ko, 1985. Fishing gear. Kyo-mun Ltd, Korea, pp. 77
  9. Kim. M.N., K.H. Kim, H.J. Jin, J.K. Park and J.S. Yoon, 2001. Biodegradability of ethyl and n-octyl branched poly((ethylene adipate) and poly(butylene succinate). European Polymer Journal, 37, 1843-1847
  10. Kim, S.H., I. J. Chin, J.S. Yoon, K.H. Lee, M.N. Kim and J.S. Jung, 1998. Biodegradation blends of PCL and starch graft derivatives. Polymer(Korean), 22(2), 335-343
  11. Kim, S.M., S.S. Im and Y.U. Choi, 1996. Preparation and properties of biodegradation starch graft copolymer. Polymer(Korean), 20(6), 949-959
  12. Kim. Y.J., S.I. Lee and B.Y. Shin, 2000. Mechanical properties, biodegradable and weatherability of poly(butylene succinate)/calcium carbonate composite. Applied chemistry, 4(1), 77-80
  13. Kint, Darwin P.R., A. Alla, E. Deldret, Josefina L. Campos and M. G. Sebastian, 2003. Synthesis, characterization, and porperties of poly(ethylene terephthalate)/poly(1,4-butylene succinate) block copolymers. Polymer, 44, 1321-1330
  14. Ko, K.S., B.T. Kim and K.H. Kang, 1970. Strength tests of imported nylon 6 and its variation after dying. J. Kor. Soc. Fish. Tech., 6, 14-22
  15. Lee, W.K., J.H. Ryou and C.S. Ha, 2002. Degradation mechanism of biodegradable polymers. polym. Sci. Tech., 13(1), 65-74
  16. Lim, M.J., J.H. Sim, J.M. Choi and Y.S. Kim, 2005. A study on development of eco-friendly wrap using biodegradable resin. J. Korean Ind. Eng. Chem., 16(6), 800-808
  17. Nikolic, M. S., D. Poleti and J. Djonlagic, 2003. Synthesis and characterization of biodegradable poly(butylene succinate-co-butylene fumarate)s. European Polymer Journal, 39, 2183-2192
  18. National Fisheries Research & Development Institute (NFRDI), 2002. Fishing gear of Korea. pp.446-568
  19. Okada, M., 2002. Chemical syntheses of biodegradable polymers. Prog. Polym. Sci., 27, 87-133
  20. Park, S.W., C.D. Park, J.H. Bae and J.H. Lim, 2007. Catching efficiency and development of the biodegradable monofilament gill net for snow crab, Chionoecetes opilio. J. Kor. Soc. Fish. Tech., 43(1), 28-43
  21. Prado, J., 1990. Fisherman's workbook. Fishing news books, Oxford, pp. 13
  22. Qiu, Z., M. Komura, T. Ikehara and T. Nishi, 2003. Miscibility and crystallization behavior of biodegra dation blends of two aliphatic polysters. poly (butylene succinate) and poly(e caprolactone). Polymer, 44, 7749-7756
  23. Ryu, K.E. and Y.B. Kim, 1998. Biodegradation of polymers. Polym. Sci. Tech.,9(6), 464-472
  24. Thomas, S.N. and C. Hridayanathan, 2006. The effect of natural sunlight on the strength of polyamide 6 multifilament and monofilament fishing net materials. Fisheries Research, 81, 326-330
  25. Tschernij, V. and P.O. Larsson, 2003. Ghost fishing by lost gill nets in the baltic sea. Fisheries Research, 64, 151-162

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  3. Economic analysis of biodegradable snow crab gill net model project vol.45, pp.4, 2009,
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  7. Fishing power estimation of biodegradable traps in the East Sea vol.46, pp.4, 2010,
  8. Preparation and physical properties of biodegradable polybutylene succinate/polybutylene adipate-co-terephthalate blend monofilament by melt spinning vol.46, pp.3, 2010,
  9. Investigation of cause and magnitude of scale effect occurring in model experiments of fishing nets vol.47, pp.1, 2011,
  10. The Durability of Polybutylene Succinate Monofilament for Fishing Net Twines by Outdoor Exposure Test vol.25, pp.4, 2013,
  11. Calculation of weight on netting with the changes of size and number of mesh for monofilament gill net fishing gear vol.48, pp.4, 2012,
  12. Catching efficiency of biodegradable trammel net for swimming crab (Portunus trituberculatus) in the Yeonpyeong fishing ground of Korea vol.48, pp.4, 2012,
  13. Practical engineering approaches and infrastructure to address the problem of marine debris in Korea vol.60, pp.9, 2010,
  14. Effects of heat setting temperature conditions on the mechanical properties of Polybutylene succinate (PBS) monofilament yarn after net-making vol.48, pp.1, 2012,
  15. Development of the biodegradable octopus pot and its catch ability comparison with a Polyethylene (PE) pot vol.47, pp.1, 2011,
  16. Catching efficiency of biodegradable trap for swimming crab (Portunus trituberculatus) in the western sea of Korea vol.50, pp.3, 2014,
  17. Catch and cluster analysis according to net materials of gillnet for the Pacific herring in the coastal waters of Samcheok, Korea vol.51, pp.3, 2015,
  18. Estimation of economic benefits of biodegradable fishing net by using contingent valuation method (CVM) vol.46, pp.3, 2010,
  19. Use of biodegradable driftnets to prevent ghost fishing: physical properties and fishing performance for yellow croaker vol.19, pp.4, 2016,
  20. Fishing performance of a coastal drift net in accordance with materials of the environmentally-friendly biodegradable net twine vol.54, pp.2, 2018,