The objective of this study was to investigate the fiber properties of Acacia decurrence as a alternative raw material quality evaluation for pulp and paper production. Trees from an even-aged stand with a similar stem diameter class were selected randomly. Wood discs were cross cut systematically from a log at the bottom (10%), middle (50%), and top (90%) position along the merchantable height, as well as a block of wood (2cmx2cmx2cm), was taken from pith to periphery: at near pith (10%), middle(50%), and near bark (90%) of disk radius. Fiber properties were determined, and their change with tree height and distance from the pith to the bark were evaluated. The fiber length, fiber width, lumen diameter, and cell wall thickness were measured while the derived fiber values were computed from the measured fiber dimensions. All the data were analyzed using a two-way analysis of variance. The results showed that the overall means were 1.37mm, 39.60µm, 9.68µm, 1.93µm, 0.39, 35.38, 24.82, and 0.09 for fiber length, fiber width, lumen diameter, cell wall thickness, Runkle ratio, slenderness ratio, flexibility coefficient, and wall coverage ratio, respectively. A.decurrence was found to fulfill most of the derived fiber values for pulp and paper production, as any part of the tree portion along tree heights and from the pith to the periphery can be utilized for pulp and paper production.
The objective of this study was to investigate the fiber properties of Acacia decurrence as an alternative raw material quality evaluation for pulp and paper production. Trees from an even-aged stand with a similar stem diameter class were selected randomly. Wood discs were cross cut systematically from a log at the bottom (10%), middle (50%), and top (90%) position along the merchantable height, as well as a block of wood (2cmx2cmx2cm), was taken from pith to periphery: at near pith (10%), middle(50%), and near bark (90%) of disk radius. Fiber properties were determined, and their change with tree height and distance from the pith to the bark were evaluated. The fiber length, fiber width, lumen diameter, and cell wall thickness were measured while the derived fiber values were computed from the measured fiber dimensions. All the data were analyzed using a two-way analysis of variance. The results showed that the overall means were 1.37mm, 39.60µm, 9.68µm, 1.93µm, 0.39, 35.38, 24.82, and 0.09 for fiber length, fiber width, lumen diameter, cell wall thickness, Runkle ratio, slenderness ratio, flexibility coefficient, and wall coverage ratio, respectively. A.decurrence was found to fulfill most of the derived fiber values for pulp and paper production, as any part of the tree portion along tree heights and from the pith to the periphery can be utilized for pulp and paper production.
The study aimed to examine the chemical composition of Acacia melanoxylon wood as a potential raw material for pulp and paper manufacturing. Samples of Acacia melanoxylon were taken systematically based on tree height at the bottom (10%), middle (50%), and top (90%) of market height. The sample was sorted, dried, milled, and sieved, and all chemical compositions were determined by the standards outlined in ASTM except cellulose and hemicellulose, which were determined by the Kurschner-Hoffer and alkali extraction methods, respectively. The results of the study showed that the overall average values of chemical composition along tree height levels were 45.02%, 21.94%, 23.79%, 5.52%, 3.24% and 0.48% for cellulose, hemicellulose, Klason lignin, hot-water solubility, alcohol-benzene extracts, and ash content, respectively. Except for hot-water extractives, the chemical composition of the bottom and top portions differed significantly. Generally, this study suggests that the chemical composition of Acacia melanoxylon wood is well suited for pulp and paper production.
The aim of this study was to investigate the fiber properties and pulp and paper-making potential of Eucalyptus globulus grown in Farta Woreda, Amhara National Regional State, Ethiopia. Six trees with an age of eight years were sampled, and sample discs were taken at the bottom (10%), middle (50%) and top (90%) along the tree height, as well as 2x2x2 cm blocks of wood at 10%, 50% and 90% of the disc radius (distance from the pith to the bark of the tree). Fiber properties were determined, and their variation along tree height and transversally from pith to bark was evaluated. The results showed that the overall mean values along tree height and distance from the pith to the bark were 0.77mm for fiber length, 12.38µm for fiber diameter, 2.94µm for cell wall thickness, 8.23µm for lumen diameter, 19.61µm for fiber width, 0.74 for runkel ratio, 39.22% for slenderness ratio, 67.83% for flexibility coefficient, and 0.47 for wall coverage ratio. Fiber length, lumen and fiber diameter, fiber width, cell wall thickness, runkel, and wall coverage ratio decreased from the bottom to the top of the tree, while they increased transversally from the pith to the bark, except for lumen diameter and flexibility coefficient, which decreased transversally from the pith to the bark, whereas the flexibility coefficient value increased from the bottom to the top of the tree height. Slenderness ratio did not show significant variation along tree height, while it showed an increase transversally from the pith to the bark.
The fiber characteristics and basic density of Acacia melanoxylon were investigated for its potential as a raw material for pulp and paper production. Six trees from the even-aged stand and similar diameter class were selected randomly from the Chencha district of Ethiopia. Wood disks were systematically cross-cut from a log along tree height levels, at the bottom (10%), middle (50%) and top (90%) of the merchantable height and blocks of wood (2 cm x 2 cm x 2 cm) were taken from pith to periphery at near pith (10%), middle (50%) and near bark (90%) of disk radius. Fiber maceration and basic density were determined, by 50% nitric acid solution and water displacement method respectively. All the data were analyzed using a two-way analysis of variance at α = 0.05. The fiber characteristics of the selected trees; the fiber length, fiber diameter, lumen diameter and cell wall thickness were measured while the-slenderness ratio, Runkel ratio, flexibility coefficient and wall coverage ratio of the fibers were derived from the measured fiber dimensions. The result showed that- the overall mean were, 1.04 mm, 21.60 µm, 15.36 µm, 3.75 µm, 0.48, 48.05%, 71.10%, 0.34 and 0.56 g/ml, for fiber length, fiber width, lumen diameter, cell wall thickness, Runkle ratio, slenderness ratio, flexibility ratio, wall coverage ratio and basic density, respectively. Generally, Acacia melanoxylon wood is suitable for pulp-and-paper-production, to due-to-its adequate-fiber dimension, derived fiber value and basic density. Therefore, attention should be given to tree growers, government and non-governmental organizations on the plantation expansion of Acacia melanoxylon.
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