A method for producing microcrystalline cellulose based on bio-damaged wood

In order to reduce the negative consequences of exposure to pests, as well as to improve the sanitary and forest pathology condition of forests, the Ministry of Forestry of the Krasnoyarsk Krai conducts sanitary logging of dead and bio-damaged wood in affected forest areas. In this regard, the problem of disposal of bio-damaged wood is acute.

This paper shows the possibility of obtaining cellulose from bio-damaged wood. The mechanical strength characteristics of the finished castings, after grinding the fibrous mass on a knife-less grinding plant of the “jet– barrier” type, are analyzed. The conditions for obtaining microcrystalline cellulose from bio-damaged wood are determined.

1. Bolezni i vrediteli khvoynykh i metody bor'by s nimi [Elektronnyy resurs]. URL: https://floraprice.ru/ articles/sad/xvojnye-i-vechnozelenye-rasteniya/boleznikhvoynykh.html (data obrashcheniya: 01.03.2022).

2. Baranchikov Yu. N., Pet’ko V. M. Ussuriyskiy poligraf – novyy agressivnyy vreditel’ pikhty v Sibiri // Vestnik MGUL – Lesnoy vestnik. 2020. № 4.

3. GOST 11208–82. Tsellyuloza drevesnaya (khvoynaya) sul’fatnaya nebelenaya: mezhgosudarstvennyy standart: data vvedeniya 1983-01-01 [Elektronnyy resurs] / Razrabotan i vnesen Ministerstvom lesnoy, tsellyuloznobumazhnoy i derevoobrabatyvayushchey promyshlennosti SSSR // Elektronnyy fond pravovykh i normativnotekhnicheskikh dokumentov: sayt. URL: https://docs. cntd.ru/document/1200017905 (data obrashcheniya: 20.02.2022).

4. Kutovaya L. V. Kompleksnyy parametr protsessa obrabotki voloknistykh suspenziy beznozhevym sposobom v ustanovke tipa “struya–pregrada” : dis. … kand. tekhn. nauk. Krasnoyarsk, 1998. 150 s. 5. Marchenko R. A. Intensifikatsiya beznozhevogo razmola voloknistykh polufabrikatov v tsellyuloznobumazhnom proizvodstve : dis. … kand. tekhn. nauk. Krasnoyarsk, 2016. 161 s.

5. Alashkevich Yu. D. Osnovy teorii gidrodinamicheskoy obrabotki voloknistykh materialov v razmol’nykh mashinakh : dis. … d-ra tekhn. nauk. L., 1980. 334 s.

6. Kaplyov E. V., Yurtayeva L. V., Alashkevich Yu. D., Vasilyeva D. Yu. Marchenko R. A. Investigation of the possibility of obtaining powdered cellulose using a nonknife method of grinding fibrous semi-finished products. APITECH III 2021. Journal of Physics: Conference Series. 2094 (2021) 042069. Doi: 10.1088/1742-6596/2094/4/042069.

7. Kanavellis R. Struynyy udar i kavitatsionnoye razrusheniye // Teoreticheskiye osnovy inzhenernykh raschetov. M., 1968. T. 90, № 3. S. 39–98.

8. Sunayt V. N. Polucheniye poroshkovoy tsellyulozy iz drevesnoy massy : dis. … kand. tekhn. nauk: 05.21.03. SPb., 2019. 134 s.

9. González, I., Alcalà, M., Chinga-Carrasco, G. et al. From paper to nanopaper: evolution of mechanical and physical properties. Cellulose 21, 2599–2609 (2014).

10. Habibi Y., Lucia L. A., Rojas O. J. Cellulose nanocrystals: chemistry, self-assembly, and applications // Chemistry Review. 2010. № 6. 3479 pp. // Ioelovich M. Cellulose nanostructured natural polymer. Saarbrücken: Lambert Academic Publishing, 2014. 77 pp.

11. Pat. 2478664 S2 Rossiyskaya Federatsiya. Sposob polucheniya poroshkovoy tsellyulozy / Frolova Svetlana Valer’yevna; zayavl. 16.05.2011; opubl. 10.04.2013. 8 s.

12. Pat. 2528261 O Rossiyskaya Federatsiya. Sposob polucheniya mikrokristallicheskoy tsellyulozy / Torlopov Mikhail Anatol’yevich; zayavl. 22.03.2013; opubl. 10.09.2014. 7 s.

13. Pat. 2684082 O Rossiyskaya Federatsiya. Sposob polucheniya mikrokristallicheskoy tsellyulozy / Nikol’skiy Sergey Nikolayevich; zayavl. 11.04.2018; opubl. 03.04.2019. 10 s.

14. Prakticheskiye raboty po khimii drevesiny i tsellyulozy / A. V. Obolenskaya, V. P. Shchegolev, G. L. Akim i dr. M. : Lesn. prom-t’, 1985. 412 s.