Abstract
Understanding the failure modes of curved hollow tree trunks is essential from both safety and conservation perspectives. Despite extensive research, the underlying mechanism that determines the cracking failure of curved hollow tree trunks remains unclear due to the lack of theoretical analysis that considers both the initial curvature and orthotropic material properties. Here we derive new mathematical expressions for predicting the bending moment, Mcrack, at which the cracking failure occurs. The failure mode of a tree species is then determined, as a function of t/R and cR, by comparing Mcrack with Mbend, where t, R and c are, respectively, the trunk wall thickness, outer radius and initial curvature; Mbend is the bending moment for conventional bending failure. Our equation shows that Mcrack is proportional to the tangential tensile strength of wood σT, increases with t/R, and decreases with the final cR. We analyse 11 tree species and find that hardwoods are more likely to fail in conventional bending, whereas softwoods tend to break due to cracking. This is due to the softwoods' much smaller tangential tensile strength, as observed from the data of 66 hardwoods and 43 softwoods. For larger cR, cracking failure is easier to occur in curvature-decreasing bending than curvature-increasing due to additional normal tensile force F acting on the neutral cross-section; on the other hand, for smaller cR, bending failure is easier to occur due to decreased final curvature. Our formulae are applicable to other natural and man-made curved hollow beams with orthotropic material properties. Our findings provide insights for those managing trees in urban situations and those managing for conservation of hollow-dependent fauna in both urban and rural settings.
Highlights
Slender hollow structures have the merit of resisting bending moment and torque with a relatively lower weight per unit royalsocietypublishing.org/journal/rsos R
Equations (2.2) and (2.14) show that Mcrack is proportional to the tangential tensile strength of wood σT, increases with The critical ratio (t/R) and decreases with the final dimensionless curvature provided that cR ≥ 0 and cR ≥ 2 K for the curvature-increasing and curvature-decreasing conditions, respectively
Using Zelkova serrata as an example, we find that, for larger cR, cracking failure is easier to occur for curvature decrease than curvature increase, i.e. Mdec/Minc < 1, due to additional normal tensile force F acting on the neutral cross-section; on the other hand, for smaller cR bending failure is easier to occur due to decreased final curvature
Summary
Slender hollow structures have the merit of resisting bending moment and torque with a relatively lower weight per unit royalsocietypublishing.org/journal/rsos R. The exact failure mode of a trunk depends on its material properties and geometric parameters The former includes (i) the ratio t/R of wall thickness t to outer radius R, (ii) the initial curvature c; the latter includes Young’s modulus E, bending strength in the longitudinal direction σb, and tangential component of tensile strength perpendicular to fibres σT, called tangential tensile strength hereafter. It depends on the wind direction if the trunk is initially curved. We compare the material properties, as a function of specific gravity, between hardwoods and softwoods for 66 species of hardwoods and 43 species of softwoods
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