PREPARATION AND PERFORMANCE EVALUATION OF CELLULOSE–BASALT FIBER HYBRID COMPOSITES FOR THERMAL AND ACOUSTIC INSULATION
Article Sidebar
Main Article Content
Abstract
This study presents the development of cellulose–basalt fiber hybrid composite materials for thermal and acoustic insulation applications using cellulose derived from agricultural biomass. The composites were fabricated through mechanical mixing and compression molding, and their physical, mechanical, and structural properties were investigated. The results demonstrated strong interfacial bonding between the cellulose matrix and basalt fiber reinforcement, leading to the formation of a stable porous structure. The developed composites exhibited low density, satisfactory mechanical strength, good thermal insulation, and effective sound absorption performance. These environmentally friendly materials, produced from renewable resources, show considerable potential as sustainable insulation materials for modern construction and engineering applications, contributing to improved energy efficiency and reduced environmental impact.
Downloads
Article Details
Issue
Section
This work is licensed under a Creative Commons Attribution 4.0 International License.
Public License Terms
(For Open Journal Systems (OJS))
-
Copyright:
The copyright of the published article remains with the author(s). However, after publication, the article is distributed on the OJS platform under the Creative Commons (CC BY) license. -
License Type:
This article is distributed under the Creative Commons Attribution 4.0 International (CC BY 4.0) license. This means users can utilize the article under the following conditions:- Copy and distribute: The text of the article or its parts can be freely distributed.
- Quote and analyze: Parts of the article can be used for quoting and analysis.
- Free use: The article can be freely used for research and educational purposes.
- Attribution: Users must provide proper attribution and reference to the original source.
-
Commercial use:
The article can be used for commercial purposes, provided that authorship and source are properly cited. -
Document modification:
The text or content of the article can be modified or adapted, as long as it does not harm the authorship. -
Liability disclaimer:
The author(s) are responsible for the accuracy of the information contained in the article. The editorial team of the platform is not liable for any damages resulting from the use of this information. -
Public usage obligations:
The content of the article must be used only in accordance with legal and ethical standards. Unauthorized use is strictly prohibited.
Note:
These license terms are designed to ensure transparency and openness in material usage. By accepting these terms, you agree to the adaptation and distribution of the article content under the terms of the Creative Commons license.
Link: Creative Commons Attribution 4.0 International (CC BY 4.0)
How to Cite
References
[1] Elievich, C. L., Khasanovich, Y. S., & Murodovich, M. M. (2021). Technology for the production of paper composites for different areas from fiber waste.
[2] Ibragimovna, Y. G. (2022). Advantages of the credit-module system in the field of education. International Journal of Social Science & Interdisciplinary Research, 11, 14–16.
[3] Itolmasovna, K. S. (2022). Development of marketing properties of processed lemon. The American Journal of Agriculture and Biomedical Engineering, 4(2), 21–25. DOI: https://doi.org/10.37547/tajabe/Volume04Issue02-05
[4] Khudayarova, S. I. (2022). Features of morphological leaf formation in lemon (Citrus limon L.) in sheltered places. Stability and Leading Research Online Scientific Journal, 15–18.
[5] Murodov, M. M. (2011). Technology of making cellulose and its ethers by using raw materials. In Proceedings of the International Conference "Renewable Wood and Plant Resources: Chemistry, Technology, Pharmacology, and Medicine" (pp. 142–143). Saint Petersburg, Russia.
[6] Murodov, M. M. (2011). The technology of making carboxymethylcellulose (CMC) by monoapparatus method. In Proceedings of the International Conference "Renewable Wood and Plant Resources: Chemistry, Technology, Pharmacology, and Medicine" (pp. 141–142). Saint Petersburg, Russia.
[7] Murodov, M. M., Rahmanberdiev, G. R., Khalikov, M. M., Egamberdiev, E. A., Negmatova, K. C., Saidov, M. M., & Mahmudova, N. (2012). Endurance of high molecular weight carboxymethylcellulose in corrosive environments. AIP Conference Proceedings, 1459(1), 309–311. DOI: https://doi.org/10.1063/1.4738479
[8] Murodov, M. M., Xudoyarov, O. F., & Urozov, M. Q. (2018). Technology of carboxymethylcellulose production using local raw materials. Advanced Engineering Forum, 8–9, 411–412.
[9] Murodov, M. M., Yusupova, N. F., Urabjanova, S. I., Turdibaeva, N., & Siddikov, M. A. (2021). Obtaining PAC from the cellulose of sunflower, safflower plants, and textile industry waste.
[10] Murodov, M. M., Yusupova, N. F., Urabjanova, S. I., Turdibaeva, N., & Siddikov, M. A. (2021). Obtaining a PAC from the cellulose of sunflower, safflower plants and waste from the textile industry. European Journal of Humanities and Educational Advancements, 2(1), 13–15.
[11] Murodovich, M. M., Murodovich, H. M., & Qulturaevich, U. M. (2020). Obtaining technical carboxymethylcellulose increased in the main substance. Academicia: An International Multidisciplinary Research Journal, 10(12), 717–719. DOI: https://doi.org/10.5958/2249-7137.2020.01795.4
[12] Murodovich, M. M., Qulturaevich, U. M., & Mahamedjanova, D. (2018). Development of technology for the production of cellulose from tissue plants and obtaining Na-carboxymethylcellulose based on it. JournalNX, 6(12), 407–411.
[13] Murodovich, M. M., Qulturaevich, U. M., & Mahamedjanova, D. (2018). Comparative research of the composition and properties of CMC in different degrees of polymerization. JournalNX, 6(12), 412–415.
[14] Primkulov, M. T., Rahmonberdiev, G., Murodov, M. M., & Mirataev, A. A. (2014). Processing technology of cellulose-containing raw materials. Uzbekistan National Society of Philosophers Publishing House.
[15] Qodirova, G. O. Q., & Xudoyorova, F. (2021). The role of educational technologies in language teaching. Scientific Progress, 2(3), 894–898.
[16] Rahmonberdiev, G., Murodov, M., Negmatova, K., Negmatov, S., & Lysenko, A. (2012). Effective technology for obtaining carboxymethyl cellulose from annual plants. Advanced Materials Research, 413, 541–543. DOI: https://doi.org/10.4028/www.scientific.net/AMR.413.541
[17] Rahmanberdiyev, G. R., & Murodov, M. M. (2011). Development of a technology for obtaining cellulose from Jerusalem artichoke plants. Economics and Innovative Technologies, 2, 1–11.
[18] Resolution of the Cabinet of Ministers of the Republic of Uzbekistan. (2020, August 27). On measures for the construction of fast-growing and industrial pavlovnia tree plantations in the Republic (Resolution No. 520).
[19] Shermatova, G. Y. H. (2022). Use of information technologies in teaching exact sciences. Scientific Progress, 3(1), 372–376. DOI: https://doi.org/10.30525/978-9934-26-277-7-269
[20] Teshabaeva, O., Yuldasheva, G., & Yuldasheva, M. (2021). Development of electronic business in the Republic of Uzbekistan. Internauka, 3(3), 16–18.
[21] Yuldasheva, G. I., & Shermatova, K. M. (2021). The use of adaptive technologies in the educational process. Economics and Society, 4(1), 466–468.
[22] Yuldasheva, G. I., & Teshabaeva, O. N. (2020). Development of the digital economy of the Republic of Uzbekistan. Universum: Economics and Jurisprudence, 7(72), 4–6.
[23] Yuldasheva, M. (2021). Effective management of investment activity in information and communication technologies of Uzbekistan. Student Bulletin, 3(4), 11–13.
[24] Xalq So‘zi. (2020). Pavlovniya plantatsiyalari hududlarda barpo etiladi. https://xs.uz/