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HomeKey Engineering MaterialsKey Engineering Materials Vol. 670Integrated Flowsheet for Conversion of Non-Woody...

Integrated Flowsheet for Conversion of Non-Woody Biomass into Polyfunctional Materials

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Abstract:

In order to develop a process to produce polyfunctional materials from easily renewable plant biomass, an integrated flowsheet has been devised on the basis of Russian Miscanthus and oat hulls for the conversion of non-woody raw materials into cellulose, cellulose esters, glucose hydrolyzates, ethanol, and bacterial cellulose by using simple chemical agents, commercially available enzyme complexes, and microorganisms. The basic physicochemical properties of the target products were determined by standard chemical and biotechnological techniques.

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Multifunctional Chemical Materials and Technologies

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Periodical:

Key Engineering Materials (Volume 670)

Pages:

202-206

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.670.202

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Online since:

October 2015

Authors:

Vera Budaeva*, Ekaterina I. Makarova, Yulia A. Gismatulina

Keywords:

Cellulose Nitrates, Ethanol, Glucose, Integrated Flowsheet, Miscanthus, Oat Hulls, Polyfunctional Cellulose

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© 2016 Trans Tech Publications Ltd. All Rights Reserved

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[1] N. Brosse, A. Dufour, X. Meng, Q. Sun, A. Ragauskas, Miscanthus: a fast-growing crop for biofuels and chemicals production, Biofuels, Bioprod. Bioref. 6 (2012) 580-598.

DOI: 10.1002/bbb.1353

[2] C. Somerville, Feedstocks for lignocellulosic biofuels, Science 329 (2010) 790-792.

[3] R-C. Sun, Cereal straw as a resource for sustainable biomaterials and biofuels, First edition, Elsevier, Amsterdam, (2010).

[4] F. Hu, A. Ragauskas, Pretreatment and lignocellulosic chemistry, Bioenergy Research 5 (2012) 1043-1066.

[5] D.B. Jordan, M.J. Bowman, J.D. Braker, B.S. Dien, R.E. Hector, C.C. Lee, J.A. Mertens, K. Wagschal, Plant cell walls to ethanol, Biochem. J. 442 (2012) 241-252.

DOI: 10.1042/bj20111922

[6] V.K. Shumny, S.G. Veprev, N.N. Nechiporenko, T.N. Goryachkovskaya, N.M. Slynko, N.A. Kolchanov, S.E. Peltek, A new form of Miscanthus (Chinese silver grass, Miscanthus sinensis – Andersson) as a promising source of cellulosic biomass, Advances in Bioscience and Biotechnology 1 (2010).

DOI: 10.4236/abb.2010.13023

[7] Yu.A. Gismatulina, V.V. Budaeva, S.G. Veprev, G.V. Sakovich, V.K. Shumny, Cellulose from various parts of Soranovskii Miscanthus, Russian Journal of Genetics: Applied Research 5, (2015) 60-68.

DOI: 10.1134/s2079059715010049

[8] M.A. F. de la Ossa, M. Lopez-Lopez, M. Torre, C. Garcıa-Ruiz, Analytical techniques in the study of highly-nitrated nitrocellulose, Trends in Analytical Chemistry (2011) 1740-1755.

DOI: 10.1016/j.trac.2011.06.014

[9] E.I. Makarova, V.V. Budaeva, E.A. Skiba, Enzymatic hydrolysis of cellulose from oat husks at different substrate concentrations, Russ. J. Bioorg. Chem. 40 (2014) 726-732.

DOI: 10.1134/s1068162014070103

[10] A.A. Yakusheva, Cellulose nitrates from a new cellulose source – oat husks, The Fundamental Researches 8 (2014) 360-364.

[11] A.A. Yakusheva, V.V. Budaeva, Synthesis optimization of cellulose nitrates having colloxyline properties from oat hulls, Polzunov Bulletin (Polzunivskiy Vestnik, in Russian) 3 (2014) 164-168.

[12] I.N. Pavlov, A Setup for studying the biocatalytic conversion of products from the processing of nonwood raw materials, Catalysis in Industry 6 (2014) 355-360.

DOI: 10.1134/s207005041404014x

[13] O.V. Baybakova, Fermentation of enzymatic hydrolyzate of Miscanthus cellulose by Pachysolen Tannophilus Y-1532 and Saccharomyces Cerevisiae Y-1693, Fundamental Researches (Fundamentalnie Issledovania, in Russian) 9 (2014) 949-953.

[14] O.V. Baibakova, E.A. Skiba, Conversion of oat husk lignocellulosics to bioethanol, Polzunov Bulletin (Polzunivskiy Vestnik, in Russian) 3 (2014) 181-185.

[15] O.V. Baybakova, Study into the bioethanol yield dependence on Miscanthus chemical pretreatment stages, Polzunov Bulletin (Polzunivskiy Vestnik, in Russian) 3 (2014) 156-160.

[16] O.V. Baibakova, E.A. Skiba, Biotechnological aspects of ethanol biosynthesis from Miscanthus, Russian Journal of Genetics: Applied Research 5 (2015) 69-74.

DOI: 10.1134/s2079059715010025

[17] E.K. Gladysheva, Study Into biosynthesis of bacterial cellulose by Мedusomyces Gisevii J. Lindau on media with different initial glucose concentration, Fundamental Researches (Fundamentalnie Issledovania, in Russian) 2 (2015) 13-17.

[18] D-P. Sun, B. Ma, C-L. Zhu, C-S. Liu, J-Z. Yang, Novel nitrocellulose made from bacterial cellulose, J. Energ. Mater. 28 (2010) 85-97.