Wood Permeability in Eucalyptus grandis and Eucalyptus dunnii

Rezende, Raphael Nogueira; Lima, José Tarcísio; Paula, Luana Elís de Ramos e; Hein, Paulo Ricardo Gherardi; Silva, José Reinaldo Moreira da

doi:10.1590/2179-8087.022815

ABSTRACT

The objective of this study was to evaluate the flow of air and water in Eucalyptus grandis and Eucalyptus dunnii wood. Wood was collected from four trees aged 37 years in an experimental plantation of the Federal University of Lavras, Brazil. Planks were cut off the basal logs to produce specimens for air and water permeability testing. Results indicated that the longitudinal permeability to air and water of E. grandis wood were, on average, 5% and 10% higher, respectively, than that of E. dunnii wood. E. grandis and E. dunnii wood showed neither air nor water flow in the test for permeability transversal to the fibers, and longitudinal permeability to air exceeded that to water by approximately 50 fold in both species.

Keywords:
air flow; water flow; longitudinal permeability; transverse permeability

1. INTRODUCTION

Eucalyptus grandis occupies one of the largest planted areas in Brazil. This species presents high productive and technological potential and its wood is used in the pulp and paper industry, for the production of fiber panels and agglomerates, in the manufacture of furniture, as firewood and in sawmills (IBÁ, 2015Indústria Brasileira de Árvores – IBÁ. Relatório IBÁ 2015: ano base 2014. Brasília: IBÁ; 2015.; Lopes et al., 2011Lopes CSD, Nolasco AM, Tomazello M Fo, Dias CTS, Pansini A. Estudo da massa específica básica e da variação dimensional da madeira de três espécies de eucalipto para a indústria moveleira. Ciência Florestal 2011; 21(2): 315-322. http://dx.doi.org/10.5902/198050983235.
http://dx.doi.org/10.5902/198050983235... ; Soares et al., 2003Soares TS, Carvalho RMMA, Vale AB. Avaliação econômica de um povoamento de Eucalyptus grandis destinado a multiprodutos. Revista Árvore 2003; 27(5): 689-694. http://dx.doi.org/10.1590/S0100-67622003000500011.
http://dx.doi.org/10.1590/S0100-67622003... ; Souza et al., 2004Souza CR, Rossi LMB, Azevedo CP. Lima, RMB Comportamento da Acacia mangium e de clones de Eucalyptus grandis x Eucalyptus urophylla em plantios experimentais na Amazônia Central. Scientia Forestalis 2004; 65: 95-101.). Eucalyptus dunnii has been considered a silvicultural alternative for companies in the south and southeast regions of Brazil, mainly because of its rapid growth, uniformity of stands, tree shape, and frost tolerance (Florsheim et al., 2009Florsheim SMB, Couto HTZ, Lima IL, Longui EL. Variação nas dimensões dos elementos anatômicos da madeira de Eucalyptus dunnii aos sete anos de idade. Revista do Instituto Florestal 2009; 1(1): 79-91.). Among its applications, it presents adequate performance for pulp and paper, sawn lumber for structural purposes, engineering wood products, and floors.

However, difficulties in the processing and use of these wood species have been verified due to their low permeability, which directly affects chip impregnation in chemical pulping, preservative treatment, bonding, water absorption, panel finishing and, mainly, the quality of drying (Lehringer et al., 2009Lehringer CH, Richter K, Schwarze FWMR, Militz H. A review on promising approaches for liquid permeability improvement in softwoods. Wood and Fiber Science 2009; 41(4): 373-385.; Taghiyari et al., 2010Taghiyari HR, Karimi NA, Parsapajouh D, Pourtahmasi K. Study on the longitudinal gas permeability of juvenile wood and mature wood. Special Topics & Reviews in Porous Media 2010; 1(1): 31-38. http://dx.doi.org/10.1615/SpecialTopicsRevPorousMedia.v1.i1.30.
http://dx.doi.org/10.1615/SpecialTopicsR... ; Tarmian & Perré, 2009Tarmian A, Perré P. Air permeability in longitudinal and radial directions of compression wood of Picea abies L. and tension wood of Fagus sylvatica L. Holzforschung 2009; 63(3): 352-356. http://dx.doi.org/10.1515/HF.2009.048.
http://dx.doi.org/10.1515/HF.2009.048... ).

According to Kamke & Lee (2007)Kamke FA, Lee JN. Adhesive penetration in wood: a review. Wood and Fiber Science 2007; 39(2): 205-220. and Siau (1971)Siau JF. Flow in wood. Syracuse: Syracuse University; 1971., permeability is a physical property related to the ease with which fluids are transported through a porous medium under differential pressure, indicating the magnitude of flow in the material and varying according to a range of factors such as chemical and anatomical characteristics, flow direction and type of fluid, among others.

In wood, diameter, frequency and distribution of vessels, fiber length, and type of pit affect permeability, as well as the deposition of extractives, which may cause partial or total occlusion and become a barrier to liquid or gas flow (Alzate, 2004Alzate SBA. Caracterização da madeira de árvores de clones de Eucalyptus grandis, E. Saligna e E. Grandis x urophylla [thesis]. Piracicaba: Escola Superior de Agricultura “Luiz de Queiroz”, Universidade de São Paulo; 2004.; Comstock, 1970Comstock GL. Directional permeability of softwoods. Wood and Fiber 1970; 1(4): 283-289.; Lepage, 1986Lepage ES. Manual de preservação de madeiras. 2. ed. São Paulo: IPT; 1986.; Lehringer et al., 2009Lehringer CH, Richter K, Schwarze FWMR, Militz H. A review on promising approaches for liquid permeability improvement in softwoods. Wood and Fiber Science 2009; 41(4): 373-385.). Regarding flow direction, Pokki et al. (2010)Pokki JP, Laakso VV, Tikka P, Aittamaa J. Specific permeability of wood to water part 1: longitudinal specific permeability of steamed, impregnated, and kraft-cooked wood. Industrial & Engineering Chemistry Research 2010; 49(5): 2144-2154. http://dx.doi.org/10.1021/ie801901f.
http://dx.doi.org/10.1021/ie801901f... observed that wood permeability is of great variability, and the longitudinal-to-transverse permeability ratio is high. The explanation for this lies in the structure and orientation of the vessels, which facilitate longitudinal flow and play a major role in the movement of liquids (Ahmed & Chun, 2009Ahmed SA, Chun SK. Observation of liquid permeability related to anatomical characteristics in Samanea saman. Turkish Journal of Agriculture and Forestry 2009; 33(2): 155-163.).

Depending on the type of fluid that moves through the wood, permeability also presents different magnitudes. Silva et al. (2010)Silva JC, Machado GO, Deiner J, Calil C Jr. Permeability measurements of brazilian Eucalyptus. Materials Research 2010; 13(3): 281-286. http://dx.doi.org/10.1590/S1516-14392010000300002.
http://dx.doi.org/10.1590/S1516-14392010... reported that the higher the fluid viscosity, the lower the flow and permeability. Liquid-phase permeability to water is lower than gas-phase permeability due to viscosity; permeability to atmospheric air in wood is 55 times higher than that to water at the same temperature (Siau, 1984Siau JF. Transport processes in wood. New York: Springer Wood Science; 1984. http://dx.doi.org/10.1007/978-3-642-69213-0.
http://dx.doi.org/10.1007/978-3-642-6921... ). Permeability to liquids was initially determined in 1963, and the apparatus developed for its measurement still serves as the basis for the development of experimental instruments. It basically comprises manometers, a vacuum reservoir, a sample holding compartment, a burette to hold fluid, hoses, stoppers, and interconnected conical seals (Siau, 1984Siau JF. Transport processes in wood. New York: Springer Wood Science; 1984. http://dx.doi.org/10.1007/978-3-642-69213-0.
http://dx.doi.org/10.1007/978-3-642-6921... ). Gas permeability was first determined in 1969, and the equipment used to measure it is similar to that used for liquid permeability, utilizing flowmeters instead of burettes.

Despite the relevance of studies on wood permeability, currently, one of the greatest problems is the absence of norms and standardized equipment for its determination. In short, information on air and water flow in wood is scarce, especially in fast growing species such as Eucalyptus.

In this context, the aim of this study was to evaluate the air and water flow in Eucalyptus grandis and Eucalyptus dunnii wood.

2. MATERIAL AND METHODS

2.1. Vegetal material and preparation of specimens

Wood from an experimental plantation belonging to the Federal University of Lavras (UFLA) located in the municipality of Lavras, Minas Gerais state, southeastern Brazil, was used in this study. Two Eucalyptus grandis and two E. dunnii trees, aged 37 years, planted at 3.0 × 2.0 m spacing were selected, felled, and sectioned. A central board was obtained from the first log (4.0 m in length; 70.0 cm of mean diameter) of each tree. The central planks were planed and cut into battens for chemical and anatomical characterization and permeability determination. The specimens for anatomical characterization and chemical analysis were planed and sectioned in 12 smaller pieces measuring 50 × 30 × 20 mm for each treatment.

2.2. Wet chemistry

Chemical characterization was performed in wood obtained from the specimens, ground, sieved, and retained in 60 mesh in accordance with the recommendations of the following norms: NBR14853 (ABNT, 2010bAssociação Brasileira de Normas Técnicas – ABNT. NBR 14853: madeira: determinação do material solúvel em etanol-tolueno e em diclorometano e em acetona. Rio de Janeiro: ABNT; 2010b.) for total extractive content, NBR7989 (ABNT, 2010aAssociação Brasileira de Normas Técnicas – ABNT. NBR-7989: pasta celulósica e madeira: determinação de lignina insolúvel em ácido. Rio de Janeiro: ABNT; 2010a.) for lignin, and NBR13999 (ABNT, 2003Associação Brasileira de Normas Técnicas – ABNT. NBR-13999: papel, cartão, pastas celulósicas e madeira - determinação do resíduo (cinza) após a incineração a 525 °C. Rio de Janeiro: ABNT; 2003.) for mineral components. The holocellulose content was obtained by difference, using the percentage in relation to the other components.

2.3. Wood anatomy

For anatomical characterization, specimens with well-oriented rings were sectioned in cubic samples with nominal dimensions of 20 × 20 × 20 mm (microscopic analysis) and analyses of the diameter of vessel pits and vessel-ray pitting were conducted using specimens measuring 5 × 5 × 5 mm. The preparation of specimens, histological cuts, staining, and assembly of the slides followed the recommendations of COPANT (1974)Comissão Pan-americana de Normas Técnicas – COPANT. Descrição macroscópica, microscópica e geral da madeira. São Paulo: COPANT; 1974. and Johansen (1940)Johansen DA. Plant microtechnique. New York: McGraw-Hill; 1940.. The method described in Franklin (1945)Franklin GL. Preparation of thin sections of synthetic resin and wood: resin composites, and a new macerating method for wood. Nature 1945; 155(3924): 51. http://dx.doi.org/10.1038/155051a0.
http://dx.doi.org/10.1038/155051a0... adapted by Berlyn & Miksche (1976)Berlyn GP, Miksche JP. Botanical microtechnique and cytochemistry. Ames: Yowa State University; 1976. was used to prepare the material macerated from wood fragments.

Microscopic anatomical characterization was performed according to the methodology established in IAWA (1989)International Association of Wood Anatomists – IAWA. List of microscopic features for hardwood identification. IAWA Bulletin 1989; 10(3): 219-233., with the aid of an optical microscope with magnification of 100x, a camera coupled and connected to a computer, and the Image ProPlus software.

Thirty measurements were performed for each anatomical character, namely: frequency (number.mm^-2), length (μm) and diameter (μm) of vessels; frequency (number.mm^-1), length (μm) and width (μm) of rays, length (μm), width (μm) and cell wall thickness of fibers, and lumen diameter (μm).

2.4. Electronic microscopy

A scanning electron microscope (LEO EVO 40 XVP) was used to measure the pit diameters of the cell walls of the vessels and ray-vessel elements. Prior to the test, the specimens of each species had their radial longitudinal surfaces flattened using a sliding microtome and were oven dried at 70 °C for 1 hour and kept in a container with silica until test time. Specimen surface was covered with approximately 20 nm of gold using a gold evaporator apparatus (Sputtering - Bal-Tec), and the scanning electron microscopy images were obtained and measured in the LEO EVO 40 XVP device.

2.5. Permeability tests

For longitudinal and transverse permeability tests, the battens were initially transformed into a cylindrical shape with a diameter of 2.0 cm according to the Baraúna (2010)Baraúna EEP. Permeabilidade das madeiras de Amapá (Brosimum parinarioides Ducke) e Faveira (Parkia gigantocarpa Ducke) [thesis]. Lavras: Universidade Federal de Lavras; 2010. methodology. After this procedure, the cylindrical sections were cut into 50 mm long specimens for the permeability tests, yielding 48 specimens per initial specimen for each direction (longitudinal and transverse to the fibers).

Specimens were conditioned in a climatic chamber at a temperature of 20 °C ± 3 °C and relative humidity of 65% ± 5% until mass stabilization. After the acclimatization stage, the specimens were waterproofed on the lateral surface with low-flow epoxy structural adhesive. To cure the adhesive, the specimens were packed into the same climatic chamber until stabilization.

The wood permeability tests were conducted according to the methodology described in Silva (2007)Silva MR. Determinação da permeabilidade em madeiras brasileiras de florestas plantadas [dissertation]. São Carlos: Universidade de São Paulo; 2007., adapted by Baraúna (2010)Baraúna EEP. Permeabilidade das madeiras de Amapá (Brosimum parinarioides Ducke) e Faveira (Parkia gigantocarpa Ducke) [thesis]. Lavras: Universidade Federal de Lavras; 2010., in an experimental permeameter for liquids and gases, using distilled water as fluid and atmospheric air from a pump. The initial pressure was based on the average monthly pressure of the test site, referenced in Brasil (1992)Brasil. Ministério da Agricultura e Reforma Agrária. Departamento Nacional de Meteorologia. Normais climatológicas: série 1961/1990. Brasília: INMET; 1992..

Wood permeability to air according to Darcy’s law was determined by Equation 1:

K a r = \frac{Q \times L \times P}{A \times Δ P \times \bar{P}}

(1)

where: K_ar = air permeability, cm³.cm^-1.atm^-1.s^-1; L = length in the direction of flow, cm; P = initial pressure, atm; A = sectional area of the specimen, cm²; ΔP = differential between initial and final pressure, atm; $\bar{P}$ = arithmetic mean between initial and final pressure, atm; Q = flow obtained in the rotameter, cm³.s^-1.

Permeability to water was also determined based on Darcy's Law using Equation 2:

K L = \frac{V \times L}{t \times A \times Δ P}

(2)

where: K_L = permeability to distilled water, cm³.cm^-1.atm^-1.s^-1; V = volume of the drained liquid, cm³; L = length in the direction of flow, cm; t = time of liquid flow, s; A = cross-sectional area, cm²; ΔP = differential between initial and final pressure, atm.

2.6. Data analysis

Data was statistically assessed by means of descriptive analysis, with determination of mean values of the chemical and anatomical properties and permeability of wood according to species with their respective coefficients of variation.

3. RESULTS AND DISCUSSION

The mean values and the coefficients of variation of the chemical properties, anatomical features, and permeability of Eucalyptus grandis and Eucalyptus dunnii wood are presented in Table 1.

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Table 1
Mean values of the chemical and anatomical properties and permeability of Eucalyptus grandis and Eucalyptus dunni wood.

The wood of E. grandis and E. dunnii trees evaluated in this study did not present air and water flow in the test for permeability transversal to the fibers. Similar findings were reported by Baraúna (2010)Baraúna EEP. Permeabilidade das madeiras de Amapá (Brosimum parinarioides Ducke) e Faveira (Parkia gigantocarpa Ducke) [thesis]. Lavras: Universidade Federal de Lavras; 2010. for two Amazonian wooden species (faveira and amapá) and by Silva (2007)Silva MR. Determinação da permeabilidade em madeiras brasileiras de florestas plantadas [dissertation]. São Carlos: Universidade de São Paulo; 2007. for Pinus elliottii wood. Kininmonth (1971)Kininmonth JA. Permeability and fine structure of certain hardwoods and effects on drying: 1., transverse permeability of wood to micro-filtered water. Holzforschung 1971; 25(4): 127-133. http://dx.doi.org/10.1515/hfsg.1971.25.4.127.
http://dx.doi.org/10.1515/hfsg.1971.25.4... reported a relationship between longitudinal and transverse permeability of approximately 10⁶ in Eucalyptus wood, mainly due to the small pit diameter of this species. Nasroun & Al-Shahrani (1998)Nasroun TH, Al-Shahrani TSS. The relationship between anatomical structure and some physical propertiesof wood: the relationship between anatomical properties and permeability of wood. Arab Gulf Journal of Scientific Research 1998; 16(3): 657-676. considered cell wall thickness as a significant factor influencing the low magnitude of permeability transverse to fibers, whereas Siau (1971)Siau JF. Flow in wood. Syracuse: Syracuse University; 1971. reported extremely low transverse permeability. Moreover, the currently used instruments present limitations in determining low-magnitude liquid and gas flow through wood.

3.1. Influence of chemical composition on wood permeability

Table 1 shows that extractive content was 10% lower and lignin content was 8% higher in E. grandis wood compared with those of E. dunnii wood. These results are superior to those described in Silva et al. (2005)Silva JC, Matos JLM, Oliveira JTS, Evangelista WV. Influência da idade e da posição ao longo do tronco na composição química da madeira de Eucalyptus grandis Hill ex. Maiden. Revista Árvore 2005; 29(3): 455-460. http://dx.doi.org/10.1590/S0100-67622005000300013.
http://dx.doi.org/10.1590/S0100-67622005... and Latorraca (1996)Latorraca JVF. Estudo da viabilidade de uso da espécie Eucalyptus dunnii (Maid) na manufatura de painéis madeira-cimento [dissertation]. Curitiba: Universidade Federal do Paraná; 1996.. However, it is worth noting that, according to Silva et al. (2005)Silva JC, Matos JLM, Oliveira JTS, Evangelista WV. Influência da idade e da posição ao longo do tronco na composição química da madeira de Eucalyptus grandis Hill ex. Maiden. Revista Árvore 2005; 29(3): 455-460. http://dx.doi.org/10.1590/S0100-67622005000300013.
http://dx.doi.org/10.1590/S0100-67622005... , with increased age and enhanced classification, the extractive and lignin contents present a growth trend. Milota et al. (1995)Milota MR, Tschernitz JL, Verrill SP, Mianowski T. Gas permeability of plantation Loblolly pine. Wood and Fiber Science 1995; 27(1): 34-40. considered that higher extractive content became a barrier to flow, especially of liquids, as can be observed in Table 1, where E. dunnii wood presents lower permeability.

E. grandis wood presented a 20% lower mineral content than that of E. dunnii, and the values were higher than those found by Rocha (2011)Rocha CD. Efeito da vaporização na madeira de Eucalyptus grandis sobre as suas propriedades químicas e resistência natural a fungos e cupins [dissertation]. Botucatu: Universidade Estadual Paulista; 2011., who reported that the amount of inorganic materials in Eucalyptus wood rarely exceed 1.0%.

As for the holocellulose content, the highest means were observed in E. dunnii wood. The holocellulose contents of E. grandis and E. dunnii wood were lower than those found by Silva et al. (2005)Silva JC, Matos JLM, Oliveira JTS, Evangelista WV. Influência da idade e da posição ao longo do tronco na composição química da madeira de Eucalyptus grandis Hill ex. Maiden. Revista Árvore 2005; 29(3): 455-460. http://dx.doi.org/10.1590/S0100-67622005000300013.
http://dx.doi.org/10.1590/S0100-67622005... and Pereira et al. (2000)Pereira JCD, Sturion JA, Higa AR, Higa RCV, Shimizu JY. Características das madeiras de algumas espécies de eucalipto plantadas no Brasil. Colombo: EMBRAPA Florestas; 2000. for the same species with ages between 10 and 25 years. They affirmed that the holocellulose contents are lower in mature trees compared with those of younger ones.

3.2. Wood anatomy controls wood permeability

Regarding wood anatomy, it was possible to observe that the frequency of vessels for E. dunnii was superior to that of E. grandis, although vessel length and diameter were smaller. These observations are in agreement with those reported by Rocha et al. (2004)Rocha FT, Florsheim SMB, Couto HTZ. Variação das dimensões dos elementos anatômicos da madeira de árvores de Eucalyptus grandis Hill ex Maiden aos sete anos. Revista do Instituto Florestal 2004; 16(1): 43-55. and Ahmed & Chun (2009)Ahmed SA, Chun SK. Observation of liquid permeability related to anatomical characteristics in Samanea saman. Turkish Journal of Agriculture and Forestry 2009; 33(2): 155-163. for Eucalyptus wood, considering that smaller vessel diameter is usually accompanied by higher frequency in wood, and that vessel diameter has a closer relation with permeability - a tendency observed for E. grandis wood, which was more permeable than E. dunnii wood.

The results obtained for the dimensions and frequency of vessels and the length and width of rays of E. grandis and E. dunnii wood are consistent with those observed by Batista (2012)Batista DC. Modificação térmica da madeira de Eucalyptus grandis em escala industrial pelo processo brasileiro vap holzsysteme® [thesis]. Curitiba: Universidade Federal do Paraná; 2012. and Florsheim et al. (2009)Florsheim SMB, Couto HTZ, Lima IL, Longui EL. Variação nas dimensões dos elementos anatômicos da madeira de Eucalyptus dunnii aos sete anos de idade. Revista do Instituto Florestal 2009; 1(1): 79-91., who worked with the same species with ages of 18 and 7 years, respectively. Nevertheless, it should be noted that the rays had greater influence on the transverse fluid movement, which was not observed in this study.

Analysis of the characteristics of the fibers revealed that E. grandis wood presents smaller fiber length and width and cell wall thickness than E. dunnii wood, but greater fiber diameter. The results found for E. grandis wood were lower than those obtained by Alzate (2004)Alzate SBA. Caracterização da madeira de árvores de clones de Eucalyptus grandis, E. Saligna e E. Grandis x urophylla [thesis]. Piracicaba: Escola Superior de Agricultura “Luiz de Queiroz”, Universidade de São Paulo; 2004. and Batista (2012)Batista DC. Modificação térmica da madeira de Eucalyptus grandis em escala industrial pelo processo brasileiro vap holzsysteme® [thesis]. Curitiba: Universidade Federal do Paraná; 2012., who also worked with E. grandis aged 8 and 18 years, respectively. They observed the following mean values: fiber length between 1030.00 and 1120.00 μm, fiber width from 20.99 to 21.50 μm, lumen diameter from 9.60 to 12.80 μm, and cell wall thickness up to 7.00 μm. Regarding E. dunnii wood, only the values for fiber length and cell wall thickness were distinct and superior to those described by Florsheim et al. (2009)Florsheim SMB, Couto HTZ, Lima IL, Longui EL. Variação nas dimensões dos elementos anatômicos da madeira de Eucalyptus dunnii aos sete anos de idade. Revista do Instituto Florestal 2009; 1(1): 79-91., who reported mean values of 860.00 and 4.33 μm for the two characteristics, respectively. With respect to lumen diameter, these authors found a mean value of 8.38 μm, higher than that presented in Table 1.

Analysis of the diameter of the intervessel and ray-vessel pits showed that E. dunnii wood presented values 10% and 15% lower than those of E. grandis wood, respectively. The diameters of intervessel and ray-vessel pits obtained in this study are similar to those reported by Alzate (2004)Alzate SBA. Caracterização da madeira de árvores de clones de Eucalyptus grandis, E. Saligna e E. Grandis x urophylla [thesis]. Piracicaba: Escola Superior de Agricultura “Luiz de Queiroz”, Universidade de São Paulo; 2004. and Lopes (2013)Lopes OP. Anatomia e identificação da madeira de genótipos de Eucalyptus spp. plantados no Estado de Minas Gerais [dissertation]. Lavras: Universidade Federal de Lavras; 2013., who found ray-vessel pits with diameter values between 4.45 and 6.25 μm and intervessel diameter measures ranging from 3.00 to 6.10 μm for Eucalyptus wood. Ahmed & Chun (2011)Ahmed SA, Chun SK. Permeability of Tectona grandis L. as affected by wood structure. Wood Science and Technology 2011; 45(3): 487-500. http://dx.doi.org/10.1007/s00226-010-0335-5.
http://dx.doi.org/10.1007/s00226-010-033... highlighted the strong influence of pit diameter on the flow of liquids between cells and on wood permeability, which may explain the higher values for permeability to air and water observed in E. grandis wood.

3.3. Wood permeability

Mean values of longitudinal permeability to air and water in E. grandis wood were 5% and 10% higher, respectively, compared with those in E. dunnii, mainly due to their chemical and anatomical characteristics.

Differences between the permeability of wood to water and air were observed, considering that, according to Siau (1971)Siau JF. Flow in wood. Syracuse: Syracuse University; 1971., the viscosity of water is 55 times higher than that of atmospheric air at 20 °C. In addition, water can bind to wood because of the hygroscopicity of the material, reducing fluid flow. Based on the values of permeability to air and water in E. grandis and E. dunnii wood (Table 1), the ratio between them obtained in this study for both species was 50:1, close to that of water and air viscosities, whereas Silva et al. (2010)Silva JC, Machado GO, Deiner J, Calil C Jr. Permeability measurements of brazilian Eucalyptus. Materials Research 2010; 13(3): 281-286. http://dx.doi.org/10.1590/S1516-14392010000300002.
http://dx.doi.org/10.1590/S1516-14392010... obtained a ratio of 59:1 for Corymbia citriodora wood.

In this study, the average permeability values of the investigated wood species were lower than those reported by Pinheiro (2013)Pinheiro MA. Influência da dimensões da madeira na secagem e nas propriedades do carvão vegetal [dissertation]. Viçosa: Universidade Federal de Viçosa; 2013. for Eucalyptus urophylla wood, with mean air permeability of 108.49 cm³.cm^-1.atm^-1.s^-1; however, these values are close to those reported by Baraúna (2010)Baraúna EEP. Permeabilidade das madeiras de Amapá (Brosimum parinarioides Ducke) e Faveira (Parkia gigantocarpa Ducke) [thesis]. Lavras: Universidade Federal de Lavras; 2010., who found longitudinal permeability to both air and water equal to 64.53 cm³.cm^-1.atm^-1.s^-1 and 2.10 cm³.cm^-1.atm^-1.s^-1, respectively, for amapá wood, an amazon hardwood species.

4. CONCLUSIONS

Based on the results obtained, we conclude that:

The longitudinal permeability to air and water of E. grandis wood was, on average, 5% and 10% higher than that of E. dunnii, probably because E. dunnii presents higher extractive content and fiber length, as well as smaller vessel and pit diameters;
E. grandis and E. dunnii showed neither air nor water flow in the test for permeability transversal to the fibers, and longitudinal permeability to air exceeded that to water by approximately 50 fold in both species.

ACKNOWLEDGEMENTS

The authors would like to thank CAPES, CNPq and FAPEMIG.

FINANCIAL SUPPORT CAPES.

REFERENCES

Ahmed SA, Chun SK. Observation of liquid permeability related to anatomical characteristics in Samanea saman. Turkish Journal of Agriculture and Forestry 2009; 33(2): 155-163.
Ahmed SA, Chun SK. Permeability of Tectona grandis L. as affected by wood structure. Wood Science and Technology 2011; 45(3): 487-500. http://dx.doi.org/10.1007/s00226-010-0335-5
» http://dx.doi.org/10.1007/s00226-010-0335-5
Alzate SBA. Caracterização da madeira de árvores de clones de Eucalyptus grandis, E. Saligna e E. Grandis x urophylla [thesis]. Piracicaba: Escola Superior de Agricultura “Luiz de Queiroz”, Universidade de São Paulo; 2004.
Associação Brasileira de Normas Técnicas – ABNT. NBR-13999: papel, cartão, pastas celulósicas e madeira - determinação do resíduo (cinza) após a incineração a 525 °C. Rio de Janeiro: ABNT; 2003.
Associação Brasileira de Normas Técnicas – ABNT. NBR-7989: pasta celulósica e madeira: determinação de lignina insolúvel em ácido Rio de Janeiro: ABNT; 2010a.
Associação Brasileira de Normas Técnicas – ABNT. NBR 14853: madeira: determinação do material solúvel em etanol-tolueno e em diclorometano e em acetona Rio de Janeiro: ABNT; 2010b.
Baraúna EEP. Permeabilidade das madeiras de Amapá (Brosimum parinarioides Ducke) e Faveira (Parkia gigantocarpa Ducke) [thesis]. Lavras: Universidade Federal de Lavras; 2010.
Batista DC. Modificação térmica da madeira de Eucalyptus grandis em escala industrial pelo processo brasileiro vap holzsysteme® [thesis]. Curitiba: Universidade Federal do Paraná; 2012.
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Publication Dates

Publication in this collection
2018

History

Received
18 Nov 2015
Accepted
14 Apr 2017

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] FINANCIAL SUPPORT CAPES.

Properties	*Eucalyptus* *Grandis*	*Eucalyptus* *Dunnii*
Total extractives (%)	9.26 (16.6)	10.48 (18.9)
Lignin (%)	27.82 (1.9)	25.74 (1.63)
Holocellulose (%)	61.28 (2.8)	61.72 (3.1)
Mineral components (%)	1.64 (12.9)	2.06 (14.6)
Frequency of vessels (nº.mm^-2)	13.00 (14.3)	16.10 (18.8)
Length of vessels (μm)	241.60 (19.8)	219.30 (21.1)
Diameter of vessels (μm)	125.50 (13.6)	107.70 (14.7)
Frequency of rays (nº.mm^-1)	13.83 (18.8)	14.19 (18.1)
Length of rays (μm)	204.04 (23.4)	235.02 (17.0)
Width of rays (μm)	14.41 (15.6)	12.16 (14.5)
Diameter of intervessel pits (μm)	3.12 (20.6)	2.78 (23.1)
Diameter of ray-vessel pits (μm)	5.39 (14.8)	4.59 (15.6)
Fiber length (μm)	971.22 (14.1)	1003.75(13.8)
Fiber width (μm)	18.51 (17.6)	20.64 (18.9)
Diameter of lumen fiber (μm)	7.69 (26.3)	7.03 (29.3)
Cell wall thickness (μm)	5.70 (20.4)	6.48 (19.8)
Longitudinal permeability to air (cm³.cm^-1.atm^-1.s^-1)	69.24 (24.3)	65.88 (29.7)
Longitudinal permeability to water (cm³.cm^-1.atm^-1.s^-1)	1.47 (55.8)	1.33 (57.5)