Determinação do módulo de elasticidade da madeira em função da inclinação das fibras utilizando tomógrafo acústico

Carrasco, Edgar Vladimiro Mantilla; Souza, Marina de Faria; Pereira, Lívia Ramos Santos; Vargas, Caio Brant

doi:10.1590/s1517-707620170005.0271

Cited by 3 publications

(4 citation statements)

References 17 publications

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“…Few studies have been performed to determine the MOEd of a specimen by pulse tomography; most researchers use voltage wave emission or transverse vibration. However, Carrasco et al (2017), who used the acoustic tomograph, concluded that it could be helpful for determining the modulus of elasticity in the fibres by only one experimental test. This work confirms the need to agree on a standard classification for the dynamic method; it is needed because too little is known about these tests of live trees in the Amazon and the values obtained.…”

Section: Dynamic Elasticity Modulusmentioning

confidence: 99%

Wave Propagation Technology in Non-destructive assays for Wood Qualifying in Tropical Amazon

Barros

Higuchi

Nascimento

et al. 2019

Int J Innov Educ Res

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Non-destructive tests use techniques which allow a body to be evaluated without changing its physical, mechanical and dimensional features and without compromising its future use. Impulse tomography analysis is a non-destructive method which allows a piece of wood to be analyzed by passing mechanical waves through it, allowing researchers to evaluate its qualities in advance and detect the presence of defects. This research reports the assessment of the efficiency of impulse tomography as a technique for identifying defects and the in situ evaluation of tree wood from Amazonian timber species. The data were collected at INPA's Tropical Forestry Experimental Station (ZF-2), located at BR 174, Manaus/AM, in a plot 1 (one) hectare in size, where 7 species were chosen at random. For evaluation, the ARBOTOM pulse tomograph at DAP (diameter at breast height) was used to rapidly capture cross sectional images of the wood. Next, the trees were cut to evaluate cross sections of the wood by eye and samples were taken to determine the density of the wood. The results enabled researchers to detect the presence of distinct zones in the wood by varying the mechanical wave speed indicated by various colour zones revealed in the X-ray. These colour differences are attributable to variations in density related to the different wood substances in the tree. It was found that the wood density and mechanical wave velocity correlated with R² 0.647. The dynamic elastic modulus of the species studied was satisfactory, showing a good degree of resistance. Impulse tomography technique provides complete information and can assist forest managers to make a decision about tree felling that is guided by the assessment of the internal quality of the wood.

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Section: Dynamic Elasticity Modulusmentioning

confidence: 99%

Wave Propagation Technology in Non-destructive assays for Wood Qualifying in Tropical Amazon

Barros

Higuchi

Nascimento

et al. 2019

Int J Innov Educ Res

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“…Other studies validated the use of tomography to determine the physical properties of wood, such as resistographic amplitude (Rollo et al, 2013), moisture content (Putri et al, 2017); Latorraca et al, 2011), and mechanical properties (Young and shear modulus) (Gonçalves et al, 2014;Gonçalves et al, 2011;Sedik et al, 2010), elasticity modulus (Carrasco et al, 2017), knots interference, juvenile wood, and reaction wood (Palma et al, 2018). Also, research was carried out to determine the pith´s location (Perlin et al, 2018) and address aspects related to wood anisotropy (Perlin et al, 2019;Arciniegas et al, 2014).…”

Section: Introductionmentioning

confidence: 96%

“…Impulse tomography is based on the propagation of mechanical stress waves generated from hammer shocks (Mendes and Silva Filho, 2019;Carrasco et al, 2017;Castro et al, 2011). The emission and capture of signals, which result in time and distance information, with which propagation speed is calculated, is done by sensors attached to the trunk by metal nails (Heidelberg, 2011).…”

Section: Introductionmentioning

confidence: 99%

Oleoresin prospection in Copaifera sp. trees by using impulse tomography

Martins

Santos

Latorraca

2021

CERNE

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Background: Copaiba oil (Copaifera L.) is a raw material used by pharmaceutical, cosmetic, and energy industries. However, the difficulty in locating the oleoresin reservoirs, is an obstacle to its continued supply, affecting the sustainable commercialization of the product. So, the potential of impulse tomography for prospecting oleoresin reservoirs in the trunk of 18 Copaifera sp. trees was tested, in cross-sections at heights levels 0% (DBH), 25%, 50%, 75%, and 100% (1st fork). The impulse tomography prospections (ITP) were performed only at the 0%, in others 12 trees, because of the risk associated with climbing hollow trees. In total 30 trees were tested. Altogether 102 tomograms were analyzed obtaining: average mechanical wave propagation speed (aMPS), minimum mechanical wave propagation speed (minS) and maximum mechanical wave propagation speed (maxS), prospecting height (Hp%) and total tree height (Ht), diameter at the Hp% (Dhp), and low speed mechanical wave propagation percentage areas (LSa%). These variables were analyzed using multivariate analysis. Results:The reservoirs were located exclusively at DBH and confirmed by borer prospection increment in 26.7% of the trees. ITP resulted in 37.3% of correct answers and 62.7% of errors, considering the 99 tomograms. However, it was found that the ITP is efficient to indicate sections for which no significant reservoir or hollow presence is expected to be found. The analysis of the main components showed that, except for Ht, the components are good indicators for the location of the reservoirs. Conclusion:We were able to use tomography to search reservoirs with a significant amount of oleoresin, identify hollow trees, and indicate the exclusion of trees that do not have reservoirs or other alterations.

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“…In order to use wood in construction, it is necessary to determine its physical and mechanical properties [21,22] according to specific Standard Codes, such as Brazilian [23] and European [24]. However, when it is impossible to produce specimens [25] or pieces present structural dimensions [26], nondestructive tests are performed by different techniques, including transverse vibration [27,28], acoustic tomography [29] and ultrasound [30]. In addition, it is also possible to estimate wood properties as a function of other known properties using regression models [31][32][33][34].…”

Section: Introductionmentioning

confidence: 99%

Estimation of Modulus of Elasticity in Static Bending of Wood in Structural Dimensions as a Function of Longitudinal Vibration and Density

Cavalheiro¹,

Almeida²,

Almeida³

et al. 2018

CJAST

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In order to use wood in a sustainable and rational way, it is necessary to estimate its characteristics, and in the case of civil construction, the physical and mechanical properties are the most interesting. The aim of this research was to estimate the modulus of elasticity of structural pieces of Original Research ArticleSchizolobium amazonicum Herb. wood through static bending (MOE sb ) and longitudinal vibration (MOE lv ) methods, in addition, to generate regression models to estimate the modulus of elasticity of static bending. Tests for MOE sb and MOE lv estimation were carried out according to ABNT NBR 7190:1997 and FAKOPP Enterprise, respectively. Linear and quadratic regression models were used to estimate MOE sb as a function of MOE lv . A multivariate regression model was also generated considering the wood density. According to the discussion of the obtained results, MOE lv and MOE sb average values estimated for the studied batch of Schizolobium amazonicum Herb. wood were 9.70 and 9.07 GPa, and average density 381.21 kg/m³. Regression models proposed for estimation of MOE sb presented the coefficient of determination close to 60%.

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Determinação do módulo de elasticidade da madeira em função da inclinação das fibras utilizando tomógrafo acústico

Cited by 3 publications

References 17 publications

Wave Propagation Technology in Non-destructive assays for Wood Qualifying in Tropical Amazon

Wave Propagation Technology in Non-destructive assays for Wood Qualifying in Tropical Amazon

Oleoresin prospection in Copaifera sp. trees by using impulse tomography

Estimation of Modulus of Elasticity in Static Bending of Wood in Structural Dimensions as a Function of Longitudinal Vibration and Density

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