用声学技术估计木材性能-第2部分:从时域和频域参数估计极限拉应力

IF 0.8 4区工程技术 Q3 FORESTRY

Wood and Fiber Science Pub Date : 2020-10-28 DOI:10.22382/wfs-2020-037

C. A. Senalik, F. França, R. D. Seale, R. Ross, R. Shmulsky

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引用次数: 6

摘要

这篇研究文章总结了一项研究的第一部分的结果，该研究旨在研究使用先进的信号处理技术和基于声学的木材评估技术来评估结构木材的MOE和极限拉应力(UTS)。在本研究的第一部分中，利用基础力学推导了理想试样中声波行为的数学模型。在第二部分中，波浪行为在一系列38 × 38 × 2438-mm的木材样本中进行了实验研究。这些标本在视觉特征上差别很大。一些标本，从视觉评估，清除自然发生的缺陷，如结。相反，在一些样品中可以看到降低强度的缺陷，如结。天然缺陷的存在会以多种方式影响声波。一些例子包括改变波速，改变波的传播路径，和/或通过模式转换将波从纵波转换成横波或转换回来。这些变化可能导致波浪行为偏离在透明木材样品中观察到的行为。在时域和频域都可以观察到偏差。从差异中识别出改进UTS估计的参数。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Estimating lumber properties with acoustic-based technologies—Part 2: Ultimate tension stress estimation from time- and frequency-domain parameters

This research article summarizes results from Part 1 of a study designed to examine the use of advanced signal processing techniques with acoustic-based lumber assessment technologies to evaluate the MOE and ultimate tension stress (UTS) of structural lumber. In Part 1 of this research, a mathematical model of acoustic wave behavior in an idealized specimen is derived using fundamental mechanics. In Part 2, wave behavior is examined experimentally in a series of 38 × 38 × 2438-mm wood specimens. The specimens vary considerably in visual character. Several of the specimens are, from a visual assessment, clear of naturally occurring defects such as knots. Conversely, strength-reducing defects such as knots are visible in several specimens. The presence of naturally occurring defects can affect acoustic waves in a variety of ways. A few examples include altering wave speed, changing the wave travel path, and/or converting the wave from longitudinal waves to shear waves or back through mode conversion. These alterations can cause wave behavior to deviate from the behavior observed in clear wood specimens. Deviations are observable in both time and frequency domains. From the differences, parameters are identified which improve estimation of UTS.

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来源期刊

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

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.