Masumi Hasegawa

Effect of wood properties on within-tree variation in ultrasonic wave velocity in softwood

The radial variations in the velocity of longitudinal waves propagating through Japanese cedar and Japanese cypress were experimentally investigated. In addition, the tracheid length (TL), microfibril angle (MFA), air-dried density (AD), and moisture content (MC) were measured in order to determine the effect of wood properties on velocity variations within the wood trunk. For both species, the longitudinal wave velocities measured in the longitudinal direction (V(L)) exhibited minimum values near the pith. For Japanese cedar, V(L) increased from 3600m/s toward the bark and soon attained a constant value (=4500m/s). On the other hand, for Japanese cypress, V(L) kept increasing from 4000m/s near the pith to 4800m/s at the bark. These radial variations in V(L) coincided with those in the tracheid length. V(L) exhibited strong correlations with TL and MFA with a significant level of (p<0.01). These findings suggest that the TL and MFA greatly affect the radial variation in the ultrasonic wave velocity in softwood.

Acoustoelastic birefringence effect in wood I: Effect of applied stresses on the velocities of ultrasonic shear waves propagating transversely to the stress direction

The velocity changes of ultrasonic shear waves propagating transversely to the applied stress direction in wood were investigated. The wave oscillation directions were parallel and normal to the uniaxially applied stress direction. The velocities of the shear waves for both oscillations decreased as the compressive load increased, and increased as the tensile load increased. The velocity of the normally oscillated shear wave showed smaller change against the stress applied than that of the parallel oscillated wave. The initial birefringence due to the orthotropy of wood was observed without any stress. Velocity changes in the two principally oscillated shear waves were proportional to the stress within the stress range tested. The acoustoelastic birefringence effect was obtained from the velocity difference between the two shear waves. The relative difference between the two velocities (called acoustic anisotropy) was given as a function of the applied stress. The acoustoelastic birefringence constants were obtained from the relationships between the acoustic anisotropy and the applied stress.

Acoustoelastic effect of wood. III. Effect of applied stresses on the velocity of ultrasonic waves propagating normal to the direction of the applied stress

Changes in the velocity of ultrasonic waves propagating in wood normal to the direction of applied stresses are discussed. The ultrasonic modes considered here are longitudinal waves and shear waves with particle motion along the direction of the applied stress. The ultrasonic velocities in wood were measured by the sing-around method. From the results of the acoustoelastic experiments in wood, changes in the ultrasonic velocities were expressed as a function of the applied stress. For the shear waves, the ultrasonic velocities decreased with an increase in compressive stress from the initial stress level. On the other hand, the ultrasonic velocities under tensile stress increased with an increase in stress at low stress levels and then gradually decreased with further a increase in the stress. In contrast, the longitudinal wave velocities increased with an increase in compressive stress at low stress levels and then decreased with additional increase in the stress. The wave velocities under a tensile stress decreased with an increase in the stress. The proportional relations between velocities and stresses at low stress levels are confirmed, and acoustoelastic constants were obtained from these relations. Their absolute values were smaller than those reported in previous studies but larger than those of metals. The acoustoelastic effect seemed to be almost equivalent on the sensitivity for stress measurement as the strain-gauge method.

Acoustoelastic birefringence effect in wood III: Ultrasonic stress determination of wood by acoustoelastic birefringence method

Stress conditions produced in wood were analyzed by means of the acoustoelastic birefringence method. Bending load was applied against a wood beam specimen. Under loading, ultrasonic shear waves were propagated through the breadth direction of the wood beam specimen. The velocities of shear waves polarized in the longitudinal or tangential direction of the wood beam specimen were measured with the sing-around method. Bending stresses were determined by dividing the difference between the acoustic anisotropy and the texture anisotropy by the acoustoelastic birefringence coefficient. Shear stresses were also determined. These stress distributions of the beam specimen were in good agreement with those obtained by the strain gauge method and mechanical calculation.

Acoustoelastic birefringence effect in wood II: influence of texture anisotropy on the polarization direction of shear wave in wood

Ultrasonic shear waves were propagated through the breadth direction of a wood beam which was subjected to a bending load such that it was in a plane-stress state. The oscillation direction of the shear waves with respect to the wood beam axis was varied by rotating an ultrasonic sensor, and the relationship between the shear wave velocity and the oscillation direction was examined. The results indicate that when the oscillation direction of the shear wave corresponds to the tangential direction of the wood beam, the shear wave velocity decreases sharply and the relationship between shear wave velocity and rotation angle tends to become discontinuous. When the oscillation of the shear waves occurs in the anisotropic direction of the wood beam instead of in the direction of principal stress, the shear wave velocity exhibits a peak value. In addition, the polarization direction was found to correspond to the direction of anisotropy of the wood beam according to the theory of acoustoelastic birefringence with respect to plane stress. This indicates that when the acoustoelastic birefringence method is applied to stress measurement of wood, it is appropriate to align the oscillation direction of the shear wave with the principal axial direction of anisotropy in order to carry out ultrasonic measurement.

Provenance variation in growth and wood properties of A. mangium and A. auriculiformis in Central Java, Indonesia: selecting potential hybrid parents for good performance

Wood variations among regional and local provenances of 11-year old Acacia mangium and Acacia auriculiformis in Central Java, lndonesia were investigated to obtain the basis data for selecting for superior trees. The regional provenances of Am and Aa were from Papua New Guinea (PNG) and Queensland-Australia (QLD), respectively. Wood cores were extracted at the breast height of each candidate plus trees, and used for measuring the wood propenies. First, a quick and effective method for evaluation of fiber length in an individual tree was investigated. The means at two different positions (Ft) were statistically related to the area weighted fiber length. Ft could be used as the value for the individual tree. Second, provenance variation in wood properties was evaluated by analysis of variance. Among Am provenances, both fiber length and lignin content dilfered signhicantly between PNG and QLD at the 10/o level. Fiber length of PNG (1.09mm) was longer than that of QLD (1.06 mm), and lignin contents of PNG (29.90/o) was lower than that of QLD (30.60/o). All provenances were classhied into three groups (good, medium, and poor petformance) according to the mean values for fiber length, air-dried density, and lignin content. Aa provenances could not be classhied into the good group. These results suggested some Am provenances might provide superior trees with-good performance.