Acoustic Wave Propagation in Standing Trees - Part II. Effects of Tree Diamter and Juvenile Wood

IF 0.8 4区 工程技术 Q3 FORESTRY
Fenglu Liu, Houjiang Zhang, Xiping Wang, F. Jiang, Wenhua Yu, R. Ross
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引用次数: 1

Abstract

The objective of this study was to investigate the effects of tree diameter and juvenile wood on acoustic wave propagation in standing trees. Two-layer tree models with various diameters and proportions of juvenile wood were constructed to examine the effects of these two factors on propagation patterns and velocity of acoustic waves. The simulation results and analysis indicated that acoustic wave propagation in trees is dependent on both tree diameter and propagation distance. In the context of time-of-flight (TOF) acoustic measurement on standing trees with a test span of 1.2 m, when tree diameter is 10 cm or less, or slenderness is twelve or greater, wave propagates as quasi-plane waves in tree trunk, and the tree velocity determined using the TOF method is then comparable to the log velocity measured using the acoustic resonance method. When tree diameter is 40 cm or larger, or slenderness is three or less, wave propagates as dilatational waves in the tree trunk; thus, the three-dimensional wave equation should be considered for wood property prediction. When tree diameter falls between 10 and 40 cm or slenderness falls between 3 and 12, wave propagation is in a transitional phase. Mathematical models were developed to convert the tree velocity in the transition mode to the resonance velocity. It was found that juvenile wood content resulted in a 113-m/s reduction in acoustic velocity. In addition, our analysis indicated that wave propagation in standing trees is controlled by the wood properties of entire cross section, not just the outerwood. Therefore, the wave velocity measured on standing trees reflects the global properties of the wood between the two measuring points.
声波在直立树木中的传播——第二部分。树木直径和幼龄木材的影响
本研究的目的是研究树木直径和幼龄木材对声波在直立树木中传播的影响。构建了不同直径和幼木比例的双层树模型,以检验这两个因素对声波传播模式和速度的影响。仿真结果和分析表明,声波在树木中的传播与树木直径和传播距离有关。在对试验跨度为1.2m的直立树木进行飞行时间(TOF)声学测量的情况下,当树木直径小于等于10cm,或长细比大于等于12时,波浪在树干中以准平面波的形式传播,然后使用TOF方法确定的树木速度与使用声共振方法测量的对数速度相当。当树木直径大于等于40cm,或长细比小于等于3时,波浪在树干中以膨胀波的形式传播;因此,木材性能预测应考虑三维波动方程。当树木直径在10到40厘米之间或长细比在3到12之间时,波浪传播处于过渡阶段。建立了数学模型,将过渡模式下的树木速度转换为共振速度。研究发现,幼龄木材含量导致声速降低113m/s。此外,我们的分析表明,波浪在直立树木中的传播受整个横截面的木材特性控制,而不仅仅是外部木材。因此,在直立树木上测量的波速反映了两个测量点之间木材的整体特性。
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来源期刊
Wood and Fiber Science
Wood and Fiber Science 工程技术-材料科学:纺织
CiteScore
7.50
自引率
0.00%
发文量
23
审稿时长
>12 weeks
期刊介绍: W&FS SCIENTIFIC ARTICLES INCLUDE THESE TOPIC AREAS: -Wood and Lignocellulosic Materials- Biomaterials- Timber Structures and Engineering- Biology- Nano-technology- Natural Fiber Composites- Timber Treatment and Harvesting- Botany- Mycology- Adhesives and Bioresins- Business Management and Marketing- Operations Research. SWST members have access to all full-text electronic versions of current and past Wood and Fiber Science issues.
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