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Wood Science and Technology
Erschienen in: Wood Science and Technology 4/2005

01.06.2005 | Original

Fatigue in wood-based panels. Part 2: property changes during fatigue cycling of OSB, chipboard and MDF

verfasst von: Richard J. H. Thompson, Martin P. Ansell, Peter W. Bonfield, John M. Dinwoodie

Erschienen in: Wood Science and Technology | Ausgabe 4/2005

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Abstract

Wood-based panels are viscoelastic so when a load (stress) is applied to them there is a time lag before a deflection (strain) is produced, which results in hysteresis (a loss of energy). The capture of stress versus strain hysteresis loops is a non-interruptive method of monitoring the damage produced during fatigue testing. Hysteresis loops were captured throughout the flexural fatigue testing of OSB, chipboard and MDF in four-point bending allowing the development of fatigue damage to be followed. The MDF tested had a greater mean bending strength than the OSB and chipboard. When stresses were applied to the materials as a percentage of their bending strengths, the stresses applied to the MDF samples were larger than those applied to the OSB and chipboard samples. As a result the microstrains were greater for MDF than for the chipboard and OSB. The OSB was stiffer than the chipboard and MDF, which were both of similar stiffness. The information gained from the hysteresis loops indicates that the OSB, chipboard and MDF all had fatigue limits just below 20% of their bending strengths. The fatigue limit for the MDF is likely to be slightly lower than for the chipboard and the OSB.
Vorheriger Artikel Regressional modeling of electrodialytic removal of Cu, Cr and As from CCA treated timber waste: application to sawdust

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Literatur
Bond IP (1994) The fatigue design of commercial wood composite wind turbine blades. PhD Thesis, University of Bath
Bonfield PW, Hacker CL, Ansell MP, Dinwoodie JM (1994) Fatigue and creep of chipboard. Part 1. Fatigue at R=0.01. Wood Sci Technol 28:423–435
Clad W, Schmidt-Helleraue C (1981) Fatigue testing of particleboard 2: supplementary tests. Holz Roh Werkst 39:241–248
Dinwoodie JM (1989) Wood: nature’s cellular, polymeric fibre composite. Institute of Metals, London, p 13
Dinwoodie JM, Bonfield PW (1995) Recent research on the rheological behaviour of wood based panels. In: Proceedings of COST 508, 22–23 March 1995
Dinwoodie JM, Paxton BH, Bonfield PW, Mundy JS (1995) Fatigue and creep in chipboard. Part 2: the influence of slow cyclic fatigue on the creep behaviour of chipboard at a range of stress levels and moisture contents. Wood Sci Technol 29:64–76
Gillwald W (1966) Investigations on the fatigue resistance of multiple layer particleboard. Int J Fract 6:445–449
Grossman PAU, Nakai T (1987) Deflection of wood under intermittent loading. Part 2: cycles of two days and fourteen minutes. Wood Sci Technol 21:349–360
Hacker CL (1995) Fatigue damage in wood composites. PhD Thesis, University of Bath
Kollman F, Krech H (1961) Fracture range and resistance of particleboard. Int J Fract 16:113–118
Kyanka GH (1980) Fatigue properties of wood and wood composites. Int J of Fract 16:609–616
Pritchard J, Thompson RJH, Bonfield PW, Ansell MP (1996) A comparison of the fatigue and creep performance of commercial grade chipboard, OSB and MDF based on equivalent applied stress levels. In: Proceedings of COST 508, 14–16 May 1996
Pritchard J, Ansell MP, Bonfield PW, Barlow CY, Bucur V (1997) Understanding the fatigue and creep properties of MDF, OSB and chipboard using environmental scanning electron microscopy and X-ray densitometry. In: Proceedings of IUFRO S 5.02 timber engineering, Copenhagen, Denmark, 18–30 June 1997
Sekino N, Okuma M (1985) Performance over time of construction particleboard 1. Fatigue behaviour in bending. Mokuzai Gakkaishi 31:801–806
Tanaka A, Suzuki M (1984) Bending fatigue strength of particleboard. Mokuzai Gakkaishi 30:807–813
Thompson RJH (1996) Fatigue and creep in wood-based panel products. PhD Thesis, University of Bath
Thompson RJH, Bonfield PW, Hacker CL, Dinwoodie JM, Ansell MP (1994) Creep and fatigue of chipboard in flexure. In: Proceedings of the pacific timber engineering conference, Gold Coast, Australia, pp 521–530
Thompson RJH, Bonfield PW, Dinwoodie JM, Ansell MP (1996a) Fatigue and creep in chipboard. Part 3. The effect of frequency. Wood Sci Technol 30:293–305
Thompson RJH, Bonfield PW, Dinwoodie JM, Ansell MP (1996b) Fatigue and creep in wood-based panel products: an introduction to research at the University of Bath. In: 25th Forest Products Conference CSIRO, Forestry and Forest Products, Australia, 18–21 November 1996
Thompson RJH, Ansell MP, Bonfield PW, Dinwoodie JM (2002) Fatigue in wood-based panels. Part 1: the strength variability and fatigue performance of OSB, chipboard and MDF. Wood Sci Technol 36:255–269
Tsai KT, Ansell MP (1990) The fatigue properties of wood in flexure. J Mat Sci 25:865–878
WPPF (1994) The facts on boards. Wood Panel Products Federation, Feltham, Middlesex
Yang JN, Lee LJ, Sheu DY (1992) Modulus reductions and fatigue damage of matrix dominated composite laminates. Comp Struct 22:91–100
Metadaten
Titel
Fatigue in wood-based panels. Part 2: property changes during fatigue cycling of OSB, chipboard and MDF
verfasst von
Richard J. H. Thompson
Martin P. Ansell
Peter W. Bonfield
John M. Dinwoodie
Publikationsdatum
01.06.2005
Erschienen in
Wood Science and Technology / Ausgabe 4/2005
Print ISSN: 0043-7719
Elektronische ISSN: 1432-5225
DOI
https://doi.org/10.1007/s00226-004-0277-x

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