C. A. Senalik, F. França, R. D. Seale, R. Ross, R. Shmulsky
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引用次数: 4
Abstract
This research article summarizes results from Part 1 of a study designed to examine using advanced signal processing techniques with acoustic-based lumber assessment technologies to evaluate the MOE, ultimate tension stress (UTS), and MOR of structural lumber. In Part 1 of this research article, a mathematical model of acoustic wave behavior in an idealized specimen is derived using fundamental mechanics. Published information on the physical and mechanical properties of clear, defect-free wood is input into the model to examine acoustic wave behavior. Wave behavior is then examined experimentally in a series of wood specimens. Observed wave behavior in the clear wood specimens, in both time and frequency domains, closely resembles idealized wave behavior. In Part 2 of this research article, predictions from the model are used to improve estimation of the UTS of wood specimens.
期刊介绍:
W&FS SCIENTIFIC ARTICLES INCLUDE THESE TOPIC AREAS:
-Wood and Lignocellulosic Materials-
Biomaterials-
Timber Structures and Engineering-
Biology-
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Timber Treatment and Harvesting-
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