Influence of modifiers on coked foam structure and properties formed with thermal decomposition of wood

Introduction. Currently, wood-based construction materials are in high demand in the field of construction around the globe. The study of the original wood composite in order to improve its characteristics through various methods is scientific pre-requisity for such development. When wood burns, it forms a surface coke layer, which can differ in mechanical and thermal stability. These parameters produce a significant effect on the fire resistance rating of building structures due to a change in the reduction rate of the structure useful cross section. Materials and methods. The studies carried out during the work are related to the evaluation of the characteristics of coke layer formed during thermal decomposition of wood. Thermal analysis methods, the scanning electron microscopy method and the water adsorption method were used. The original sapwood of pine, as well as the wood modified with effective fire-retardant agents were used in the course of work. Results. Based on conducted experiments process graphic dependences of thermal decomposition have been obtained, as well as images, obtained by an electronic microscope. In addition, the dependence of adsorptive capacity of wood after thermal decomposition has been obtained. Discussions. As a result of the study, it was found that with the use of modifiers based on organophosphorous compounds, entering into effective reaction with wood, structuring of the surface layer occurs after thermal decomposition while reducing the size of specific surface area of wood. Conclusions. Based on the analysis of experimental data, we can conclude that because of the use of efficient wood surface layer modifiers, thermal decomposition takes place under “mild” conditions that is the shift of the first stage of thermal decomposition to the area of lower temperatures with non-severe exothermic effects. The loss of weight of samples during combustion is significantly reduced. This causes high fire-retardant efficiency and low smoke-generating capacity.

термическое разложение, древесина, модифицирование, термогравиметрия, поверхностный слой, карбонизованный слой, thermal decomposition, timber, modification, thermogravimetry, surface layer, coke layer

1. Ксавье Деглиз. “Экологический менеджмент” лесов и изделий из древесины Лесной вестник Forestry Bulletin. -2017.-Т. 21, № 4. -С. 6-9. DOI: 10.186982542-1468-2017-4-6-9.

2. Pastori Z., Czupy I., Gorbacheva G. A. Using poplar stud elements in light frame wall structure instead of coniferous Lesnoy vestnik Forestry Bulletin. - 2017. - Vol. 21, No. 4. - P. 89-94. DOI: 10.186982542-1468-2017-4-89-94.

3. Safin R. R., Shaikhutdinova A. S., Khasanshin R. R., Akhunova L. V., Safina A. V. Improving the energy efficiency of solid wood fuel 15th International Multidisciplinary Scientific GeoConference. Surveying Geology and Mining Ecology Management : SGEM2015 Conference Proceedings. - 2015. - Book 4. - P. 315-322. DOI: 10.5593SGEM2015B41S17.041. URL: https:sgemworld.at sgemlibspip.php?article6145 (дата обращения: 10.03.2018).

4. Михалева С. А. Деревянные высотки в России-инновационный взгляд на современное строительство Международный научно-исследовательский журнал. - 2016. - № 4-7(46). - С. 19-21. DOI: 10.18454IRJ.2016.46.174.

5. Pasztory Z., Peralta P., Molnar S., Peszlen I. Modeling the hygrothermal performance of selected North American and comparable European wood-frame house walls Energy & Buildings. - 2012. - Vol. 49. -P. 142-147. DOI: 10.1016j.enbuild.2012.02.003.

6. Макишев Ж. К., Сивенков А. Б. Изучение процесса обугливания деревянных конструкций различного срока эксплуатации методами термического анализа Технологии техносферной безопасности. -2016.-№ 1(65).-С. 84-88.

7. Ройтман В. М. Инженерные решения по оценке огнестойкости проектируемых и реконструируемых зданий. -М. : Пожнаука, 2001.-382 с.

8. Joгo Pedro dos Santos Laranjeira, Helena Cruz, Ana Paula Ferreira Pinto, Carlos Pina dos Santos, Joana Filipa Pereira. Reaction to fire of existing timber elements protected with fire retardant treatments: experimental assessment International Journal of Architectural Heritage.-2015.-Vol. 9, No. 7. -P. 866-882. DOI: 10.108015583058.2013.878415.

9. Стенин А. А. Улучшение свойства строительных материалов из древесины за счет модификации ее поверхности Строительство-формирование среды жизнедеятельности : сборник докладов XVI Международной межвузовской научно-практической конференции студентов, магистрантов, аспирантов и молодых ученых. -М. : МГСУ, 2013. -С. 553-559.

10. Покровская Е. Н. Химико-физические основы увеличения долговечности древесины. - М. : Изд-во АСВ, 2003.-104 с.

11. Laurichesse S., Avйrous L. Chemical modification of lignins: Towards biobased polymers Progress in Polymer Science.-2014.-Vol. 39, No. 7.-P. 1266-1290.DOI:10.1016j.progpolymsci. 2013.11.004.

12. Антюфеева Н. В., Алексашин В. М. Применение методов термического анализа для определения показателей технологических и эксплуатационных свойств материалов Все материалы. Энциклопедический справочник. -2017.-№ 1. -С. 55-64.

13. Costa V. J., Vieira R. M., Girotto S. B. F. T. , Simioni F. J. Pyrolysis and thermogravimetry of blended and nonblended residues of pine and eucalyptus forestry woods Environmental Progress and Sustainable Energy.-2016.-Vol. 35, No. 5. -P. 1521-1528. DOI: 10.1002ep.12372.

14. Islamova S. I., Khamatgalimov A. R. Thermogravimetric and kinetic analyses of the thermal decomposition of fuel wood Solid Fuel Chemistry. - 2017. - Vol. 51, No. 2. - P. 83-87. DOI: 10.3103s0361521917020045.

15. Mar’yandyshev P. A., Chernov A. A., Lyubov V. K. Analysis of thermogravimetric data for different forms of wood Solid Fuel Chemistry. - 2015. - Vol. 49, No. 2. - P. 117-122. DOI: 10.3103s0361521915020081.

16. Панова Т. В. Современные методы исследования вещества. Электронная и оптическая микроскопия : учебное пособие.-Омск : Омский государственный университет им. Ф. М. Достоевского, 2016.-80 с.

17. Goldstein J. I., Yakowitz H. (eds.). Practical scanning electron microscopy. - New York - London : Plenum Press, 1975.-582 p. DOI: 10.1007978-1-4613-4422-3.

18. Ruthven D. М. Principles of adsorption and adsorption processes. - New York etc. : John Wiley & Sons, Inc., 1984.-433 p.

19. Кельцев Н. В. Основы адсорбционной техники. -М. : Мир, 1984. -592 с.

20. Kulasinski K., Guyer R., Derome D., Carmeliet J. Water adsorption in wood microfibril-hemicellulose system: role of the crystalline-amorphous interface Biomacromolecules.-2015.-Vol. 16, No. 9. -P. 2972-2978. DOI: 10.1021acs.biomac.5b00878.