Layer-by-Layer Dynamic Shear Modulus in the Cross-Section of a Particle Board

Authors

DOI:

https://doi.org/10.37482/0536-1036-2022-5-143-156

Keywords:

particle board, dynamic mechanical analysis, dynamic shear modulus, wood, thermosetting resin, binder curing, composite material

Abstract

The research results are aimed at the formation of ideas concerning the features of molecular motion of the components of the outer and inner layers of the particle board material in the temperature range from room temperature to 275–300 °C, as well as at revealing the fact of binder undercuring in the inner layers. The paper provides data on the temperature dependences of the dynamic shear modulus of the outer and inner layers of the particle board material, obtained by dynamic mechanical analysis using a torsion pendulum. We found significant differences in the nature of the dependencies for samples taken at different distances from the surface layers. The material of the outer layers is characterized by the typical pattern of a continuous irregularly consistent decrease in the dynamic shear modulus with increasing temperature, which is common to most polymeric and composite materials. A short-term intermittent increase in the dynamic shear modulus relative to neighboring areas was detected in the inner layers at 140±5 °C, which is not typical for materials in a stable state. There is also a tendency for the dynamic shear modulus of the particle board material to decrease at room temperature with distance from the outer layers, due to the heterogeneous fractional composition and differences in the nature of chemical cross-linking during hot pressing. It has been assumed that the detected anomalous increase in the dynamic shear modulus in the inner layers of the material at 140±5 °С is a symptom of the binder post-treatment process directly in conditions of its heating when measuring the dynamic shear modulus by dynamic mechanical analysis. Thus, it is concluded that the particle board sample shows maximum curing of the thermosetting binder in the layers, which are 4.5–5.0 mm distant from both surfaces. Partial undercuring of the binder occurs in the inner layers, which are more than 5.5 mm away from the surfaces. Thus, it is shown that the method of dynamic mechanical analysis can be used as a tool to control the presence in the inner layers of the particle board material of the components of thermosetting binder, undercured in the hot pressing process, which will help to obtain a material with more stable characteristics.
Acknowledgments: The research was carried out within the framework of the Support Program for scientific and pedagogical workers of the Altai State University, the project “Application of Digital Processing Methods for Interpretation of Experimental Data on the Structure and Properties of Wood and Wood Composite Materials”.

For citation: Skurydin Yu.G., Skurydina E.M. Layer-by-Layer Dynamic Shear Modulus in the Cross-Section of a Particle Board. Lesnoy Zhurnal = Russian Forestry Journal, 2022, no. 5, pp. 143–156. (In Russ.). https://doi.org/10.37482/0536-1036-2022-5-143-156

Downloads

Download data is not yet available.

Author Biographies

Yuri G. Skurydin, Altai State University

Candidate of Engineering

 

Elena M. Skurydina, Altai State Pedagogical University

Candidate of Engineering, Assoc. Prof.

 

References

Беушева О.С., Скурыдина Е.М., Чемерис М.М., Мусько Н.П., Скурыдин Ю.Г. Влияние условий прессования на свойства плитных материалов, изготовленных из гидротермически обработанной древесины лиственницы // Изв. вузов. Строительство. 2006. № 5(569). С. 48–50. Beusheva O.S., Skurydina E.M., Chemeris M.M., Musko N.P., Skurydin Yu.G. The Influence of Pressing Condition on Properties of Plate Materials Made of Hydrothermally Treated Larch Wood. News of higher educational institutions. Construction, 2006, no. 5(569), pp. 48–50. (In Russ.).

Васильев В.В., Хоссейни С.З. Современные требования к древесным плитам для отделки // Древесные плиты: теория и практика: XX Междунар. науч.-практ. конф. / под ред. А.А. Леоновича. СПб.: Политехн. ун-т, 2017. С. 62–71. Vasiliev V.V., Hosseini S.Z. Modern Requirements for Wood-Based Panels for Finishing. Wood-Based Panels: Theory and Practice. Proceedings of the XX International Scientific and Practical Conference. Ed. by A.A. Leonovich. Saint Petersburg, Polytechnic University Publ., 2017, pp. 62–71. (In Russ.).

Волкова С.Н., Сивак Е.Е., Панкратьева О.В., Леванов Г.В., Боев Н.В., Конотопченко О.А. Контроль качества строительных материалов из отходов лесной промышленности // Регион. вестн. 2021. № 3(59). С. 33–36. Volkova S.N., Sivak E.E., Pankrat’yeva O.V., Levanov G.V., Boyev N.V., Konotopchenko O.A. Quality Control of Building Materials from Forest Industry Waste. Regional’nyy vestnik, 2021, no. 3(59), pp. 33–36. (In Russ.).

Древесные плиты: теория и практика: XX Междунар. науч.-практ. конф. / под ред. А.А. Леоновича. СПб.: Политехн. ун-т, 2017. 122 с. Wood-Based Panels: Theory and Practice. Proceedings of the XX International Scientific and Practical Conference. Ed. by A.A. Leonovich. Saint Petersburg, SPbSTU Publ., 2017. 122 p. (In Russ.).

Ерыхов Б.П. Неразрушающие методы исследования целлюлозно-бумажных и древесных материалов. М.: Лесн. пром-сть, 1987. 228 с. Erykhov B.P. Non-Destructive Methods of Examination of Pulp and Paper and WoodBased Materials. Moscow, Lesnaya promyshlennost’ Publ., 1987. 228 p. (In Russ.).

Кархова С.А. Анализ состояния производства и торговли листовыми древесными материалами в мире // Baikal Research Journal. 2018. Т. 9, № 2. Karkhova S.A. State Analysis for Production and Trade of Boards and Plywood in the World. Baikal Research Journal, 2018, vol. 9, no. 2, art. 6. (In Russ.). https://doi. org/10.17150/2411-6262.2017.9(2).6

Отлев И.А. Интенсификация производства древесностружечных плит. М.: Лесн. пром-сть, 1989. 192 с. Otlev I.A. Intensification of Particle Board Production. Moscow, Lesnaya promyshlennost’ Publ., 1989. 192 p. (In Russ.).

Патент 2619359 C1 РФ, МПК G01N 25/00 (2006.01). Способ определения незавершенности процесса отверждения термореактивного связующего древесностружечной плиты: № 2016102862: заявл. 28.01.2016: опубл: 15.05.2017 / Ю.Г. Скурыдин, Е.М. Скурыдина. Skurydin Yu.G., Skurydina E.M. Method of Determination of the Noncompletion of the Process of the Thermoreactive Binder Curing of a Particle Board. Patent RF, no. RU 2 619 359 C1, 2017. (In Russ.).

Перепечко И.И. Акустические методы исследования полимеров. М.: Химия, 1973. 295 c. Perepechko I.I. Acoustic Research Methods for Studying Polymers. Moscow, Khimiya Publ., 1973. 295 p. (In Russ.).

Сафин Р.Г., Степанов В.В., Хайруллина Э.Р., Гайнуллина А.А., Степанова Т.О. Современные строительные композиционные материалы на основе древесных отходов // Вестн. Казан. технол. ун-та. 2014. Т. 17, № 20. С. 123–128. Safin R.G., Stepanov V.V., Khairullina E.R., Gainullina A.A., Stepanova T.O. Modern Construction Composite Materials Based on Wood Waste. Bulletin of the Technological University, 2014, vol. 17, no. 20, pp. 123–128. (In Russ.).

Скурыдин Ю.Г. Строение и свойства композиционных материалов, полученных из отходов древесины после взрывного гидролиза: дис. … канд. техн. наук. Барнаул, 2000. 147 с. Skurydin Yu.G. Structure and Properties of Composite Materials Obtained from Wood Wastes after Explosive Hydrolysis: Cand. Eng. Sci. Diss. Barnaul, 2000. 147 p. (In Russ.).

Скурыдина Е.М. Разработка технологии композиционных материалов на основе древесины и полимерных наполнителей: дис. … канд. техн. наук. Барнаул, 2006. 170 с. Skuridina E.M. Development of the Technology of Composite Materials Based on Wood and Polymer Fillers: Cand. Eng. Sci. Diss. Barnaul, 2006. 170 p. (In Russ.).

Старцев О.В., Салин Б.Н., Скурыдин Ю.Г. Баротермический гидролиз древесины в присутствии минеральных кислот // Докл. АН. 2000. Т. 370, № 5. С. 638–641. Startsev O.V., Salin B.N., Skurydin Yu.G. Barothermal Hydrolysis of Wood in Presence of Mineral Acids. Doklady Akademii Nauk, 2000, vol. 370, no. 5, pp. 638–641. (In Russ.).

Чубинский А.Н., Варанкина Г.С., Русаков Д.С. Технология древесных плит. СПб.: СПбГЛТУ, 2019. 37 с. Chubinsky A.N., Varankina G.S., Rusakov D.S. Technology of Wood-Based Panels. Saint Petersburg, SPbFTU Publ., 2019. 37 p. (In Russ.).

Шахзадян Э.А., Квачев Ю.П., Папков В.С. Температурные переходы в древесине и ее компонентах // Высокомолекулярные соединения. 1992. Т. (А) 34, № 9. С. 3–14. Shakhzadyan E.A., Kvachev Yu.P., Papkov V.S. Temperature Transitions in Wood and Its Components. Polymer Science. Series A, 1992, vol. 34, no. 9, pp. 3–14. (In Russ.).

Fengel D., Wegener G. Wood: Chemistry, Ultrastructure, Reactions. Berlin, De Gruyter, 1983. 613 p. https://doi.org/10.1515/9783110839654

Müller U., Pretschuh C., Mitter R., Knappe S. Dielectric Analysis as a Cure Monitoring System for UF Particle Boards. International Journal of Adhesion and Adhesives, 2016, vol. 73, pp. 45–50. https://doi.org/10.1016/j.ijadhadh.2016.07.016

Oktay S., Kızılcan N., Bengu B. Oxidized Cornstarch – Urea Wood Adhesive for Interior Particleboard Production. International Journal of Adhesion and Adhesives, 2021, vol. 110, art. 102947. https://doi.org/10.1016/j.ijadhadh.2021.102947

Singh N., Rana A., Badhotiya G.K. Raw Material Particle Terminologies for Development of Engineered Wood. Materials Today: Proceedings, 2021, vol. 46, part 10, pp. 11243–11246. https://doi.org/10.1016/j.matpr.2021.02.616

Skurydin Yu.G., Skuridina E.M. Physical and Mechanical Characteristics of the Thermal-Wood Composition from Hydrolyzed Birch Wood. IOP Conference Series: Earth and Environmental Science, 2019, vol. 316, art. 012066. https://doi.org/10.1088/1755- 1315/316/1/012066

Skurydin Yu.G., Skurydina E.M. Digital Differential Spectrometry in the Assessment of the Structural Characteristics of Wood and Wooden Composite Materials. IOP Conference Series: Earth and Environmental Science, 2021, vol. 806, art. 012030. https://doi. org/10.1088/1755-1315/806/1/012030

Startsev O.V., Salin B.N., Skuridin Y.G., Utemesov R.M., Nasonov A.D. Physical Properties and Molecular Mobility of the New Wood Composite Plastic “Thermobalite”. Wood Science and Technology, 1999, vol. 33, iss. 1, pp. 73–83. https://doi.org/10.1007/ s002260050100

Uemura Silva V., Nascimento M.F., Resende Oliveira P., Panzera T.H., Rezende M.O., Silva D.A.L., Borges de Moura Aquino V., Rocco Lahr F.A., Christoforo A.L. Circular vs. Linear Economy of Building Materials: A Case Study for Particleboards Made of Recycled Wood and Biopolymer vs. Conventional Particleboards. Construction and Building Materials, 2021, vol. 285, art. 122906. https://doi.org/10.1016/j.conbuildmat.2021.122906

Published

2022-10-28

How to Cite

Skurydin Ю., and Skurydina Е. . “Layer-by-Layer Dynamic Shear Modulus in the Cross-Section of a Particle Board”. Lesnoy Zhurnal (Forestry Journal), no. 5, Oct. 2022, pp. 143-56, doi:10.37482/0536-1036-2022-5-143-156.

Issue

Section

MECHANICAL TECHNOLOGY OF WOOD AND WOOD SCIENCE