Hemmasi, A., kohantorabi, M. (2017). Investigation of relationship between dynamic modulus of elasticity and static bending ‎properties in ‎particleboard plates. , 32(2), 193-204. doi: 10.22092/ijwpr.2017.109577
Amir Homan Hemmasi; mostafa kohantorabi. "Investigation of relationship between dynamic modulus of elasticity and static bending ‎properties in ‎particleboard plates". , 32, 2, 2017, 193-204. doi: 10.22092/ijwpr.2017.109577
Hemmasi, A., kohantorabi, M. (2017). 'Investigation of relationship between dynamic modulus of elasticity and static bending ‎properties in ‎particleboard plates', , 32(2), pp. 193-204. doi: 10.22092/ijwpr.2017.109577
Hemmasi, A., kohantorabi, M. Investigation of relationship between dynamic modulus of elasticity and static bending ‎properties in ‎particleboard plates. , 2017; 32(2): 193-204. doi: 10.22092/ijwpr.2017.109577

Investigation of relationship between dynamic modulus of elasticity and static bending ‎properties in ‎particleboard plates

تحقیقات علوم چوب و کاغذ ایران
Article 4, Volume 32, Issue 2 - Serial Number 59, July 2017, Pages 193-204    PDF (382.28 K)
Document Type: Research Paper
DOI: 10.22092/ijwpr.2017.109577
Authors
Amir Homan Hemmasi1; mostafa kohantorabi* 2
1Department of Wood and Paper Science and Technology College of Agriculture and Natural Resources, Science and Research ‎Branch, Islamic Azad University, Tehran, Iran
2Ph.D Student, Department of Wood and Paper Science Islamic Azad University, Science and Research Branch, Hesarak, Poonak, Tehran
Abstract
In this study the relationship between dynamic modulus of elasticity from longitudinal ‎vibration ‎method with static modulus of elasticity and bending strength in two directions: the ‎Parallel ‎machine direction and machine direction have been investigated. For this purpose 4 ‎plates of ‎particleboard with dimensions 124× 90 ×1.6 cm (length× width× thickness) were ‎selected and free ‎longitudinal vibration test in PMD and MD were performed on each plates. ‎After that the primary ‎plates were cut to four plates with dimensions 62× 44 ×1.6 cm (length× ‎width× thickness) and ‎longitudinal vibration test in PMD and MD were performed on each ‎plates again. Finally each plates ‎were cut to the beams with dimensions 36× 1.6 ×1.6 cm and ‎longitudinal vibration test and and ‎static bending test were performed on them. The results show ‎that good correlation between ‎dynamic modulus of elasticity from longitudinal vibration test ‎and static modulus of elasticity and ‎bending strength (result of beams extracted from each ‎plates) in both size of plates in two size ‎‎(124× 90 ×1.6 and 62× 44 ×1.6 cm) and beams ‎extracted from each plates in two directions (PMD ‎and MD). In addition there was good ‎correlation between dynamic modulus of elasticity of ‎longitudinal vibration from two size plates ‎‎(124× 90 ×1.6 and 62× 44 ×1.6 cm). When the samples ‎smaller than primary plates, the ‎dynamic modulus of elasticity values were increased, that it due to ‎the diffusion of waves in ‎samples with larger dimensions. In general, according to results of this ‎research it can be ‎concluded that by applying the appropriate correction factors, longitudinal ‎vibration method an ‎efficiency method for calculation of dynamic and static modulus of elasticity ‎and estimate of ‎the modulus of rupture in plates in full sized.‎
Keywords
Vibration; Plate; STATIC BENDING; Modulus of elasticity; Non-destructive
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