Journal of the Korean Wood Science and Technology

The Korean Society of Wood Science & Technology (한국목재공학회)
권호 표지
DOI QR코드

DOI QR Code

Dynamic Property of Cross-Laminated Woods Made with Temperate Seven Species

  • GONG, Do-Min (Department of Environmental Forest Science, Institute of Agriculture & Life Science, Gyeongsang National University) ;
  • SHIN, Moon-Gi (Department of Environmental Forest Science, Institute of Agriculture & Life Science, Gyeongsang National University) ;
  • LEE, Soo-Hyun (Department of Environmental Forest Science, Institute of Agriculture & Life Science, Gyeongsang National University) ;
  • BYEON, Hee-Seop (Department of Environmental Forest Science, Institute of Agriculture & Life Science, Gyeongsang National University) ;
  • PARK, Han-Min (Department of Environmental Forest Science, Institute of Agriculture & Life Science, Gyeongsang National University)
  • Received : 2021.06.02
  • Accepted : 2021.08.11
  • Published : 2021.09.25
Download PDF
⟨ Previous Next ⟩

Abstract

In this study, cross-laminated wood panels were manufactured with four softwoods and three hardwoods with the goal of efficiently predicting the static strength performance using dynamic modulus of elasticity (MOE) and simultaneously revealing the dynamic performance of cross-laminated wood panels. The effect of the density of the species on the dynamic MOE of the laminated wood panels was investigated. Moreover, the static bending strength performance was predicted nondestructively through the correlation regression between the dynamic MOE and static bending strength performance. For the dynamic MOE, the parallel- and cross-laminated wood panels composed of oriental oak showed the highest value, whereas the laminated wood panels composed of Japanese cedar showed the lowest value. In all types of parallel- and cross-laminated wood panels, the density dependence was confirmed, and the extent of the density dependence was found to be greater in the P and C types with perpendicular-direction laminae in the faces than in the P and C types with longitudinal-direction laminae in the faces. Our findings confirmed that a high correlation exists at a significance level of 1% between the dynamic modulus and static bending modulus or bending strength in all types of laminated wood panels, and that the static bending strength performance can be predicted through the dynamic MOE.

Keywords

References

  1. Ayarkwa, J., Hirashima, Y., Sasaki, Y. 2001. Predicting modulus of rupture of solid and finger-jointed tropical African hardwoods using longitudinal vibration. Forest Products Journal 51(1): 85-92.
  2. Bender, D.A., Burk, A.G., Taylor, S.E., Hooper, J.A. 1990. Predicting localized MOE and tensile strength in solid and finger-jointed laminating lumber using longitudinal stress waves. Forest Products Journal 40(3): 45-47.
  3. Byeon, H.S., Park, H.M., Kim, C.H., Lam, F. 2005a. Nondestructive evaluation of strength performance for finger-jointed woods using flexural vibration techniques. Forest Products Journal 55(10): 37-42.
  4. Byeon, H.S., Ahn, S.Y., Park, H.M. 2005b. Nondestructive evaluation of bending strength performances for red pine containing knots using flexural vibration technique. Journal of the Korean Wood Science and Technology 33(5): 13-20.
  5. Byeon, J.W., Kim, T.H., Yang, J.K., Byeon, H.S., Park, H.M. 2018. Static bending performances of cross-Laminated wood panels made with tropical and temperate woods. Journal of the Korean Wood Science and Technology 46(6): 726-734. https://doi.org/10.5658/WOOD.2018.46.6.726
  6. Cha, J.K. 1996. Study on stress waves for development of glulam from domestic small diameter log(1). Journal of the Korean Wood Science and Technology 24(3): 90-100.
  7. Choi, G.W., Yang, S.M., Lee, H.J., Kim, J.H., Choi, K.H., Kang, S.G. 2020. A study on the block shear strength according to the layer composition of and adhesive type of ply-lam CLT. Journal of the Korean Wood Science and Technology 48(6): 791-806. https://doi.org/10.5658/wood.2020.48.6.791
  8. Choi, G.W., Yang, S.M., Lee H.J., Kim, J.H., Choi, K.H., Kang, S.G. 2021. Evaluation of flexural performance according to the plywood bonding method of ply-lam CLT. Journal of the Korean Wood Science and Technology 49(2): 107-121. https://doi.org/10.5658/WOOD.2021.49.2.107
  9. Galih, N.M., Yang, S.M. Yu, S.M., Kang, S.G. 2020. Study on the mechanical properties of tropical hybrid cross laminated timber using bamboo laminated board as core layer. Journal of the Korean Wood Science and Technology 48(2): 245-252. https://doi.org/10.5658/WOOD.2020.48.2.245
  10. Hidayati, F., Lukmandaru, G., Indrioko, S., Sunarti, S., Nirsatmanto, A. 2019 Variation in tree growth characteristics, pilodyn penetration, and stress-wave velocity in 65 families of acacia mangium trees planted in indonesia. Journal of the Korean Wood Science and Technology 47(5): 633-643. https://doi.org/10.5658/wood.2019.47.5.633
  11. Jang, S.S. 2000. Evaluation of lumber properties by applying stress wav es to larch logs grown in Korea. Forest Products Journal 50(3): 44-48.
  12. Jang, S.S., Lee, H.W. 2019. Lateral resistance of CLT wall panels composed of square timber larch core and plywood cross bands. Journal of the Korean Wood Science and Technology 47(5): 547-556. https://doi.org/10.5658/wood.2019.47.5.547
  13. Kang, C.W., Jang, S.S., Kang, H.Y., Li, C. 2019. Sound absorption rate and sound transmission loss of CLT wall panels composed of larch square timber core and plywood cross band. Journal of the Korean Wood Science and Technology 47(1): 33-39. https://doi.org/10.5658/WOOD.2019.47.1.33
  14. Kataoka, A., Ono, T. 1975. The relations of experimental factors to the vibration and the measuring values of dynamic mechanical properties of wood I. The experimental errors due to the measuring apparatus. Mokuzai Gakkaishi 21(10): 543-550.
  15. Lee, D.S., Jo, J.S., Kim, G.H. 1997. Evaluation of static bending properties for some domestic softwoods and tropical hardwoods using sonic stress wave measurements. Journal of the Korean Wood Science and Technology 25(1): 8-14.
  16. Matsumoto T., Tsutsumi, J. 1968. Elastic properties of plywood in dynamic test I. Relation between static Young's modulus and dynamic Young's modulus. Mokuzai Gakkaishi 14(2): 65-69.
  17. Nakayama, Y. 1975. Non-destructive test of wooden beam by vibrational method. Estimation of modulus of rupture in bending of beam containing an artificial circular hole. Mokuzai Gakkaishi 21(7): 402-409.
  18. Norimoto, M. 1982. Structure and properties of wood used for musical instruments I. Mokuzai Gakkaishi 28(7): 407-413.
  19. Park, H.M., Byeon, H.S. 2006. Measurement of dynamic MOE of 3-ply laminated woods by flexural vibration and comparison with bending strength and creep performances. Journal of the Korean Wood Science and Technology 34(2): 46-57.
  20. Park, H.M., Fuchitani M., Byeon, H.S. Yang, J.K. 2016. Static bending strength performances of cross-laminated wood panels made with six species. Wood and Fiber Science 48(2): 68-80.
  21. Park, H.M., Gong, D.M., Shin, M.G., Byeon, H.S. 2020. Bending creep properties of cross-laminated wood panels made with tropical hardwood and domestic temperate wood. Journal of the Korean Wood Science and Technology. 48(5): 608-617. https://doi.org/10.5658/WOOD.2020.48.5.608
  22. Park, H.M., Lee, G.P., Kong, T.S., Ryu, H.S., Byeon, H.S. 2004. Effect of finger profile on static bending strength performance of finger-jointed wood. Journal of the Korean Wood Science and Technology 32(6): 57-66.
  23. Park, H.M., Lee, S.K., Seok, J.H., Choi, N.K., Kwon, C.B., Heo, H.S., Byeon, H.S., Yang, J.K., Kim, J.C. 2011. Effect of green tea content on dynamic modulus of elasticity of hybrid boards composed of green tea and wood fibers, and prediction of static bending strength performances by flexural vibration test. Journal of the Korean Wood Science and Technology 39(6): 538-547. https://doi.org/10.5658/WOOD.2011.39.6.538
  24. Sobue, N., Nakano, H., Asano, I. 1984. Vibrational properties of spruce plywood for musical instruments. Mokuzai Gakkaishi 31(1): 93-97.
  25. Tonosaki, M., Okano, T., Asano, I. 1983. Vibration properties of sitka spruce with longitudinal vibration and flexural vibration. Mokuzai Gakkaishi 29(9): 547-552.