Abstract
Japanese cedar wood was moderately compressed by 50 % in the radial (R) direction. The compressed wooden blocks were glued into the form of a beam with R directions aligned in the longitudinal direction of the beam. The compressed wooden beam (CR) showed excellent ductility and elasticity comparable to synthetic rubbers. The elastic deflection of the CR was further increased when the tensile side was reinforced by a thin compressed wooden plate (CL), because this ensured that the CR was always in a compressed state while tensile stress was supported by the CL. The CR + CL composite exhibited large deflections ten times greater than that of the original cedar lumber, a Charpy value corresponding to the high amount of energy absorbed in impact bending comparable to that of densified wood, and a large critical bending work exceeding that of uncompressed wood in the direction of the fiber. The soft and durable nature of the composite beam was attributed to the softness and elasticity of the moderately compressed wood, in which the folded cell walls behaved as flat springs.
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References
Haller P, Wehsener J, Werner TE, Hartig J (2013) Recent advancements for the application of moulded wooden tubes as structural elements. In: Aicher S, Reinhard HW, Garrecht H (eds) Material and joints in timber structures. Springer, Heidelberg, pp 99–108
Inoue M, Norimoto M, Tanahashi M, Rowell RM (1993) Steam or heat fixation of compressed wood. Wood Fiber Sci 25:224–235
Ito Y, Tanahashi M, Shigematsu M, Shinoda Y (1998) Compressive-molding of wood by high-pressure steam-treatment: part 2. Mech of perm fixat. Holzforsch 52:217–221
Kutnar A, Sandberg D, Haller P (2015) Compressed and moulded wood from processing to products. Holzforschung 69(7):885–897
Nakamura S, Futamura S, Maeno K, Yoshitani K, Tanahashi M (2009) Development of stretchable and flexible wood which possesses optimum properties for three-dimensional molding (in Japanese). Mokuzai Gakkaishi 55:77–84
Obataya E, Kitin P, Yamauchi H (2007) Bending characteristics of bamboo (Phyllostachys pubescens) with respect to its fiber–foam composite structure. Wood Sci Technol 41:385–400
Sandberg D, Haller P, Navi P (2012) Thermo-hydro and thermo-hydro-mechanical wood processing: An opportunity for future environmentally friendly wood products. Wood Math Sci Eng 8:64–88
Stamm AJ, Seborg RM (1941) Resin-treated, laminated, compressed wood. Trans Am Chem Eng 37:385–398
Stamm AJ, Burr HK, Kline AA (1946) Staybwood. Heat-stabilized wood. Ind Eng Chem 38:630–634
Wehsener J, Weser T, Haller P, Diestel O, Cherif C (2014) Textile reinforcement of multidimensional formable wood. Eur J Wood Prod 72:463–475
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The authors are very grateful to the LIXIL JS foundation for their financial support.
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Hirano, A., Obataya, E. & Adachi, K. Potential of moderately compressed wood as an elastic component of wooden composites. Eur. J. Wood Prod. 74, 685–691 (2016). https://doi.org/10.1007/s00107-016-1046-x
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DOI: https://doi.org/10.1007/s00107-016-1046-x