Journal of the Korean Wood Science and Technology

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

Measurement of Dynamic MOE of 3-Ply Laminated Woods by Flexural Vibration and Comparison with Blending Strength and Creep Performances

  • Park, Han-Min (Institute of Agriculture & Life Science, College of Agriculture & Life Science, Gyeongsang Nat'l Univ.) ;
  • Byeon, Hee-Seop (Institute of Agriculture & Life Science, College of Agriculture & Life Science, Gyeongsang Nat'l Univ.)
  • Received : 2006.01.05
  • Accepted : 2006.03.06
  • Published : 2006.03.25
Download PDF
⟨ Previous Next ⟩

Abstract

To estimate nondestructively strength performances of laminated woods, 3-ply parallel- and cross-laminated wood specimens exposed under atmosphere conditions after bending creep test were prepared for this study. The effects of density of species, arrangement of laminae and lamination types on dynamic MOE obtained by flexural vibration were investigated, and regression analyses were conducted in order to estimate static bending strength and bending creep performances. Dynamic MOE of parallel-laminated woods showed 1.0~1.2 times higher values than static bending MOE, and those of cross-laminated woods showed 1.0~1.4 times higher values than static bending MOE. The degree of anisotropy of dynamic MOE perpendicular to the grain of face laminae versus that parallel to the grain of face laminae was markedly decreased by cross-laminating. There were strong correlations between dynamic MOE by flexural vibration and static bending MOE (correlation coefficient r = 0.919~0.972) or bending MOR (correlation coefficient r = 0.811~0.947) of 3-ply laminated woods, and the correlation coefficient were higher in parallel-laminated woods than in cross-laminated woods. It indicated that static bending strength performances were able to be estimated from dynamic MOE by flexural vibration. Also, close correlations between the reciprocal of dynamic MOE by flexural vibration and initial compliance at 0.008 h of 3-ply laminated woods were found (correlation coefficient r = 0.873~0.991). However, the correlation coefficient between the reciprocal of dynamic MOE and creep compliance at 168 h of 3-ply laminated woods was considerably lower than those between dynamic MOE and initial compliance, and it was hard to estimate creep compliance with a high accuracy from dynamic MOE due to the variation of creep deformation.

Keywords

References

  1. Ayarkwa, J., Y. Hirashima, and Y. Sasaki. 2001. Predicting modulus of rupture of solid and finger-jointed tropical African hardwoods using longitudinal vibration. Forest Prod. J. 51(1): 85 -92
  2. Akitsu, H., M. Norimoto, and T. Morooka. 1991. Vibrational properties of chemically modified wood. Mokuzai Gakkaishi 37(7): 590-597
  3. Beall, F. C. and W. W. Wilcox. 1987. Relationship of acoustic emission during radial compression to mass loss from decay. Forest Prod. J. 37(4): 38-42
  4. Bender, D. A., A. G. Burk, S. E. Taylor, and J. A. Hooper. 1990. Predicting localized MOE and tensile strength in solid and finger-jointed laminating lumber using longitudinal stress waves. Forest Prod. J. 40(3): 45 -47
  5. Byeon, H. S., H. M. Park, C. H. Kim, and F. Lam. 2005a. Nondestructive evaluation of strength performance for finger-jointed woods using flexural vibration techniques. Forest Prod. J. 55(10): 37-42
  6. Byeon, H. S., S. Y. Ahn, and H. M. Park. 2005b. Nondestructive evaluation of bending strength performances for red pine containing knots using flexural vibration technique. Mokchae Konghak 33(5): 13- 20
  7. Cha, J. K. 1996. Study on stress waves for development of glulam from domestic small diameter log(l). Mokchae Konghak 24(3): 90-100
  8. Hong, B. H. 1985. The dynamic mechanical properties of paulownia coreana used for sounding boards. Mokchae Konghak 13(3): 34 - 40
  9. Jang, S. S. 2000. Evaluation of lumber properties by applying stress waves to larch logs grown in Korea. Forest Prod. J. 50(3): 44-48
  10. Kataoka, A. and T. Ono. 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
  11. Kataoka, A. and T. Ono. 1976. The dynamic Measurement of Dynamic MOE of 3.Ply Laminated Woods by Flexural Vibration and Comparison with Bending Strength and Creep Performances mechanical properties of sitka spruce used for sounding boards. Mokuzai Gakkaishi 22(8): 436 -443
  12. Lee, D. S., J. S. Jo, and G. H. Kim. 1997. Evaluation of static bending properties for some domestic softwoods and tropical hardwoods using sonic stress wave measurements. Mokchae Konghak 25(1): 8- 14
  13. Matsumoto T. and J. Tsutsumi. 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
  14. Murakami, R., H. Yamada, and K. Mori. 1971a. The dynamic viscoelasticity of hardboard pulp sheets I. Relation between hot pressing temperature and dynamic viscoelasticity. Mokuzai Gakkaishi 17(6): 243 -248
  15. 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
  16. Norimoto, M. 1982. Structure and properties of wood used for musical instruments I. Mokuzai Gakkaishi 28(7): 407 - 413
  17. Park, H. M., M. Fushitani, K. Sato, T. Kubo, H. S. Byeon. 2003. Static bending strength performances of cross-laminated woods made with five species. Journal of Wood Science 49: 411 - 417 https://doi.org/10.1007/s10086-002-0502-x
  18. Park, H. M., G. P. Lee, T. S. Kong, H. S. Ryu, and H. S. Byeon. 2004. Effect of finger profile on static bending strength performance of fingerjointed wood. MokchaeKonghak 32(6): 57 -66
  19. Park, H. M., M. Fushitani, K. Sato, T. Kubo, H. S. Byeon. 2006. Bending creep performances of three-ply cross-laminated woods made with five species. Journal of Wood Science. (in press)
  20. Sobue, N., H. Nakano, and I. Asano. 1984. Vibrational properties of spruce plywood for musical instruments. Mokuzai Gakkaishi 31(1): 93-97
  21. Tonosaki, M., T. Okano, and I. Asano. 1983. Vibration properties of sitka spruce with longitudinal vibration and flexural vibration. Mokuzai Gakkaishi 29(9): 547 - 552
  22. Wilcox, W. W. 1988. Detection of early stage of wood decay with ultrasonic pulse velocity. Forest Prod. J. 38(5): 68 -73
  23. Yano, H., T. Yamada, and K. Minato. 1986b. Changes in acoustical properties of sitka spruce due to reaction with formaldehyde. Mokuzai Gakkaishi 32(12): 984 - 989