Influence of Degree of Polymerization of Cellulose and Hemicellulose on Strength Loss in Fire-Retardant-Treated Southern Pine

Sweet, Marshall; Winandy, Jerrold E.

doi:10.1515/hf.1999.051

Cited by 90 publications

(62 citation statements)

References 5 publications

(4 reference statements)

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“…They suggest that mechanical properties, which relates to internal stress and strain, are simply functions of chemical bond strength: covalent and hydrogen intrapolymer bonds (molecular level); covalent and hydrogen interpolymer bonds and cell wall layer bonds (microscopic level); and fiber-to-fiber bonding with the middle lamella acting as the adhesive (macroscopic level). According to Sweet and Winandy [45] wood fibres can be regarded as a composite material and a single micro fibril or a group of microfibrils cannot entirely account for the strength of an entire wood fibre. The chemical-mechanical linkages between cellulose microfibrils and the lignin-hemicelluloses matrix allow load sharing among the microfibrils.…”

Section: Discussionmentioning

confidence: 99%

“…An increased cross linking of the lignin polymer network could be another reason for this improvement. Lignin acts as a stiffener of the cellulose microfibrils/fibrils [45] and an increased cross linking of this polymer appears to prevent or limit movement perpendicular to the grain (which occurs during compressive loading parallel to the grain). Furthermore, lignin is the main component of the middle lamella [15] and an increased cross linking of the lignin polymer network improves the strength of the middle lamella which subsequently affects the strength properties of the cell wall.…”

Section: Compressive Strengthmentioning

confidence: 99%

“…There appears to be a relationship between the decrease of the bending strength and the degradation of the hemicelluloses [23,29,52] and it has been suggested that changes in the hemicelluloses content and structure are primarily responsible for the initial loss of the bending strength [45,54], since hemicelluloses are the most thermal-chemically sensitive component of wood [25]. Raising the effective treatment temperature and/or increasing the treatment time during the hydro-thermolysis stage resulted in a further decrease of the bending strength (Figs.…”

Section: Bending and Impact Strengthmentioning

confidence: 99%

“…It is however rather hypothetical whether a polymer of such short DP and situated around the (amorphous) cellulose microfibrils, can contribute in this way to the strength of wood fibres. It appeared that cellulose and lignin were not affected until strength losses exceeded 30-40% [45,54], since no depolymerisation or degradation products of these polymers were observed. However, the possibility of rearrangements of the molecular structure of cellulose and/or lignin, and its effects on the strength properties of wood, were not considered (e.g.…”

Section: Bending and Impact Strengthmentioning

confidence: 99%

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Strength properties of thermally modified softwoods and its relation to polymeric structural wood constituents

Boonstra¹,

et al. 2007

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-Thermal modification at relatively high temperatures (ranging from 150 to 260 • C) is an effective method to improve the dimensional stability and resistance against fungal attack. This study was performed to investigate the impact of heat treatment on the mechanical properties of wood. An industrially-used two-stage heat treatment method under relative mild conditions (< 200 • C) was used to treat the boards. Heat treatment revealed a clear effect on the mechanical properties of softwood species. The tensile strength parallel to the grain showed a rather large decrease, whereas the compressive strength parallel to the fibre increased after heat treatment. The bending strength, which is a combination of the tensile stress, compressive stress and shear stress, was lower after heat treatment. This decrease was less than the decrease of only the tensile strength. The impact strength showed a rather large decrease after heat treatment. An increase of the modulus of elasticity during the bending test has been noticed after heat treatment. Changes and/or modifications of the main wood components appear to be involved in the effects of heat treatment on the mechanical properties. The possible effect of degradation and modification of hemicelluloses, degradation and/or crystallization of amorphous cellulose, and polycondensation reactions of lignin on the mechanical properties of heat treated wood have been discussed. The effect of natural defects, such as knots, resin pockets, abnormal slope of grain and reaction wood, on the strength properties of wood appeared to be affected by heat treatment. Nevertheless, heat treated timber shows potential for use in constructions, but it is important to carefully consider the stresses that occur in a construction and some practical consequences when heat treated timber is used. thermal modification / mechanical properties / cellulose / hemicelluloses / lignin Résumé -Propriétés mécaniques de bois résineux modifiés par traitement thermique en relation avec la constitution en polymères ligneux structuraux. La modification thermique du bois à des températures relativement élevées (entre 150 et 260 • C) présente une méthode efficace pour améliorer la stabilité dimensionnelle et la résistance aux attaques de champignons. Ce travail porte sur les effets du traitement thermique sur les propriétés mécaniques du bois. Les planches ont été soumises à un traitement thermique à des températures relativement modérées (< 200 • C) selon un procédé industriel en deux phases. Il s'est avéré qu'un tel traitement influe nettement sur les propriétés mécaniques des bois résineux. La résistance à la traction dans la direction parallèle au fil du bois est diminuée de manière assez importante, tandis que, dans la même direction, la résistance à la compression est augmentée. La résistance au fléchissement, qui intègre la résistance aux efforts de traction, de compression et de cisaillement, était plus réduite après le traitement thermique. Cette diminution était moins importante que celle de la...

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Section: Discussionmentioning

confidence: 99%

Section: Compressive Strengthmentioning

confidence: 99%

Section: Bending and Impact Strengthmentioning

confidence: 99%

Section: Bending and Impact Strengthmentioning

confidence: 99%

See 2 more Smart Citations

Strength properties of thermally modified softwoods and its relation to polymeric structural wood constituents

Boonstra¹,

et al. 2007

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“…While studying the chemical composition of Pinus oocarpa cultivated in the cerrado, Morais, Nascimento and Melo (2005) found 11.47% of extractives, 25.18% of lignin and 1.26% of ash. Higher lignin contents are desirable for particleboard production, this component having a very condensed structure and irregular aspect which provides high rigidity to the relevant material, acting as a buffer of cellulose microfibrils, limiting parallel to grain movement and increasing mechanical strength against external forces (SWEET;WINANDY, 1999).…”

Section: Chemical Analysismentioning

confidence: 99%

Use of maize cob for production of particleboard

et al. 2013

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Agricultural residues are materials generated in large quantities in Brazil and can accumulate to such extent as to cause environmental problems. Among agricultural residues, maize cob is one worthy of notice, and an alternative use for maize cob would be to produce particleboard panels in association with wood particles. This study aimed to evaluate the feasibility of using maize cob for production of particleboard panels. The following maize cob percentages were used: 0%, 25%, 50%, 75% and 100%, in association with particles of Pinus oocarpa wood. Panels were made with 8% of urea formaldehyde and 1% of paraffin (based on dry weight of particles). For compressing the panels, a pressure of 3.92 MPa was applied at a temperature of 160° C, for 8 minutes. Increased replacement of pinewood by maize cob residue promoted significant improvements to the properties water absorption after two hours of immersion, thickness swelling after two and after twenty-four hours of immersion. Mechanical properties had a decreasing correlation with the maize cob percentage being incorporated.Index terms: Environmental problems, reuse, physicomechanical properties, agricultural residues. RESUMOOs resíduos agrícolas são materiais gerados em grande quantidade no Brasil, podendo se acumular no ambiente, gerando graves problemas. Um desses resíduos que merecem destaque é o sabugo de milho. Uma das alternativas para o reaproveitamento do sabugo seria a produção de painéis aglomerados em mistura com madeira. Objetivou-se, neste trabalho, avaliar a viabilidade da utilização do sabugo de milho para a produção de painéis aglomerados. As porcentagens de sabugo de milho utilizadas foram de 0%, 25%, 50%, 75% e 100% associadas com partículas de madeira de Pinus oocarpa. Os painéis foram produzidos com 8% de uréia-formaldeído e 1% de parafina (base massa seca de partículas). Na prensagem dos painéis, foi utilizada pressão de 3,92 MPa e temperatura de 160º C por um período de 8 minutos. O aumento da substituição da madeira de pinus pelo resíduo sabugo de milho promoveu melhoras significativas para as propriedades de absorção de água, após duas horas e inchamento em espessura, após duas e vinte e quatro horas. As propriedades mecânicas apresentam relação decrescente com a porcentagem de incorporação de sabugo de milho. Termos de indexação:Problemas ambientais, reaproveitamento, propriedades físico-mecânicas, resíduos agrícolas.

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Hot compressed water extraction of polysaccharides from Ganoderma lucidum using a semibatch reactor

Matsunaga

Diono

Machmudah

et al. 2013

Asia-Pacific J Chem Eng

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Ganoderma lucidum (G. lucidum) is a mushroom‐forming white rot fungus. Although not edible, it is grown commercially for use as a medicinal supplement. In this study, G. lucidum was utilized for the extraction of polysaccharides by hot compressed water at temperatures of 373–463 K and a pressure of 4.0 MPa using a semibatch system—a most effective method because water at high temperature and pressure behaves as a reaction medium with remarkable properties. Under these conditions, thermal softening of G. lucidum occurred, allowing the removal of the polysaccharides protecting other constituents in G. lucidum via hydrolysis. The main massed peaks of water‐soluble products were distributed at around 688–2638 m/z with a peak‐to‐peak mass difference of 162 m/z, consistent with the repeating unit of the glucans. On the basis of these results, this process is proposed as applicable to the isolation of polysaccharides from other types of biomass and may lead to an advanced plant biomass components extraction technology. © 2013 Curtin University of Technology and John Wiley & Sons, Ltd.

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Influence of Degree of Polymerization of Cellulose and Hemicellulose on Strength Loss in Fire-Retardant-Treated Southern Pine

Cited by 90 publications

References 5 publications

Strength properties of thermally modified softwoods and its relation to polymeric structural wood constituents

Strength properties of thermally modified softwoods and its relation to polymeric structural wood constituents

Use of maize cob for production of particleboard

Hot compressed water extraction of polysaccharides from Ganoderma lucidum using a semibatch reactor

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