Magdalena Broda, Carmen-Mihaela Popescu, Kamil Poszwa, Edward Roszyk
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Thermal treatment at 220 °C influenced wood chemical composition, degrading mainly hemicelluloses but also affecting cellulose and lignin, which resulted in a reduction of hydroxyls and carbonyl/carboxyl groups. These changes were more pronounced for mature than juvenile wood. It reduced mass loss and swelling rate, and increased swelling pressure in the tangential and radial directions to a higher degree for juvenile than mature wood. Changes in mechanical properties in compression were statistically significant only for mature wood, while wood hardness remained unaffected. Although the applied heat treatment improved the performance of juvenile wood by reducing its swelling rate, it did not equalise the examined properties between juvenile and mature wood. Since higher juvenile wood proportion is expected in the wood supply from the future intensively managed forests, there is still a need to find suitable modification methods or better processing techniques so that instead of being thrown away as waste, it could be used broadly in various industrial applications.</p></div>","PeriodicalId":810,"journal":{"name":"Wood Science and Technology","volume":"58 3","pages":"1153 - 1180"},"PeriodicalIF":3.1000,"publicationDate":"2024-05-26","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://link.springer.com/content/pdf/10.1007/s00226-024-01561-2.pdf","citationCount":"0","resultStr":"{\"title\":\"How thermal treatment affects the chemical composition and the physical, mechanical and swelling properties of Scots pine juvenile and mature wood\",\"authors\":\"Magdalena Broda, Carmen-Mihaela Popescu, Kamil Poszwa, Edward Roszyk\",\"doi\":\"10.1007/s00226-024-01561-2\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>High variations in juvenile wood properties in the radial direction and its worse performance than mature wood make it less suitable for some applications and often treated as waste material. This study aimed to assess how thermal modification affects the chemical composition and the physical, mechanical and swelling properties of Scots pine juvenile and mature wood. An additional goal was to evaluate if the modification can equalise the differences in selected properties of juvenile wood to those of mature wood so that from waste material, juvenile wood can become a fully-fledged raw material for various industrial applications. Thermal treatment at 220 °C influenced wood chemical composition, degrading mainly hemicelluloses but also affecting cellulose and lignin, which resulted in a reduction of hydroxyls and carbonyl/carboxyl groups. These changes were more pronounced for mature than juvenile wood. It reduced mass loss and swelling rate, and increased swelling pressure in the tangential and radial directions to a higher degree for juvenile than mature wood. Changes in mechanical properties in compression were statistically significant only for mature wood, while wood hardness remained unaffected. Although the applied heat treatment improved the performance of juvenile wood by reducing its swelling rate, it did not equalise the examined properties between juvenile and mature wood. 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引用次数: 0
摘要
苏格兰松木幼木在径向上的特性差异很大,其性能比成熟木材差,因此不太适合某些应用,通常被作为废料处理。这项研究旨在评估热改性如何影响苏格兰松幼木和成熟木材的化学成分以及物理、机械和膨胀特性。研究的另一个目的是评估热改性是否能平衡幼木与成熟木材在所选特性上的差异,从而使幼木从废料变为可用于各种工业应用的成熟原材料。220 °C 的热处理会影响木材的化学成分,主要降解半纤维素,但也会影响纤维素和木质素,导致羟基和羰基/羧基减少。这些变化在成熟木材中比在幼年木材中更为明显。它降低了质量损失和膨胀率,并增加了切向和径向的膨胀压力,幼木的程度高于成熟木材。压缩机械性能的变化仅对成熟木材有显著的统计学意义,而木材硬度则不受影响。虽然热处理降低了幼木的膨胀率,从而改善了幼木的性能,但它并没有使幼木和成熟木材的检测性能相等。由于在未来集约化管理的森林供应的木材中,幼木的比例预计会更高,因此仍有必要找到合适的改性方法或更好的加工技术,使其不再被当作废物丢弃,而是能广泛用于各种工业用途。
How thermal treatment affects the chemical composition and the physical, mechanical and swelling properties of Scots pine juvenile and mature wood
High variations in juvenile wood properties in the radial direction and its worse performance than mature wood make it less suitable for some applications and often treated as waste material. This study aimed to assess how thermal modification affects the chemical composition and the physical, mechanical and swelling properties of Scots pine juvenile and mature wood. An additional goal was to evaluate if the modification can equalise the differences in selected properties of juvenile wood to those of mature wood so that from waste material, juvenile wood can become a fully-fledged raw material for various industrial applications. Thermal treatment at 220 °C influenced wood chemical composition, degrading mainly hemicelluloses but also affecting cellulose and lignin, which resulted in a reduction of hydroxyls and carbonyl/carboxyl groups. These changes were more pronounced for mature than juvenile wood. It reduced mass loss and swelling rate, and increased swelling pressure in the tangential and radial directions to a higher degree for juvenile than mature wood. Changes in mechanical properties in compression were statistically significant only for mature wood, while wood hardness remained unaffected. Although the applied heat treatment improved the performance of juvenile wood by reducing its swelling rate, it did not equalise the examined properties between juvenile and mature wood. Since higher juvenile wood proportion is expected in the wood supply from the future intensively managed forests, there is still a need to find suitable modification methods or better processing techniques so that instead of being thrown away as waste, it could be used broadly in various industrial applications.
期刊介绍:
Wood Science and Technology publishes original scientific research results and review papers covering the entire field of wood material science, wood components and wood based products. Subjects are wood biology and wood quality, wood physics and physical technologies, wood chemistry and chemical technologies. Latest advances in areas such as cell wall and wood formation; structural and chemical composition of wood and wood composites and their property relations; physical, mechanical and chemical characterization and relevant methodological developments, and microbiological degradation of wood and wood based products are reported. Topics related to wood technology include machining, gluing, and finishing, composite technology, wood modification, wood mechanics, creep and rheology, and the conversion of wood into pulp and biorefinery products.