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909 záznamů v PubMed

Článek

Carbon filter layer for respirator derived from acrylic filter felt

The present study fabricated carbon felts for respiratory filter layers through single-step pyrolysis ...

Wang, Yuanfeng
Autor Wang, Yuanfeng Department of Material Engineering, Faculty of Textile Engineering, Technical University of Liberec, Liberec, Czech Republic. Electronic address: yuanfeng.wang@tul.cz
Venkataraman, Mohanapriya
Autor Venkataraman, Mohanapriya Department of Material Engineering, Faculty of Textile Engineering, Technical University of Liberec, Liberec, Czech Republic
Křemenáková, Dana
Autor Křemenáková, Dana Department of Material Engineering, Faculty of Textile Engineering, Technical University of Liberec, Liberec, Czech Republic
Hrůza, Jakub
Autor Hrůza, Jakub Institute for Nanomaterials, Advanced Technologies and Innovation, Technical University of Liberec, Liberec, Czech Republic
Militký, Jiří
Autor Militký, Jiří Department of Material Engineering, Faculty of Textile Engineering, Technical University of Liberec, Liberec, Czech Republic

Waste management (New York, N.Y.). 2025 Feb 15 ; 194 () : 115-124. [epub] 20250109

Waste Manag
ISSN 1879-2456 | 0956-053X
Zdroj

Pyrolysis emerges as a strategy for handling waste textiles, wherein the conversion of high-carbon-content textile waste into carbonaceous materials facilitates the restoration of its economic value, concurrently mitigating the environmental impact posed by textile waste. The present study fabricated carbon felts for respiratory filter layers through single-step pyrolysis of acrylic filter felts. The advantage of employing conductive carbon felt as a respiratory filter layer is its capability to concurrently serve two functions: filtration and electrical heating for high-temperature disinfection. In order to achieve these two functions, both the respirator body and the embedded electrodes were designed to ensure the reliability of high-temperature disinfection. The breathability and water vapor permeability of the obtained carbon felt were examined to confirm its comfortability as a respiratory filter layer. The results of filtration efficiency and antimicrobial testing indicated that the carbon felt exhibited a filtration efficiency of over 90 % against inhalable particulate matter, while its antimicrobial properties effectively suppressed microbial growth. This method of reutilizing waste textiles maintained consistency in the usage of textiles before and after reuse, simplified the reusing process of waste acrylic fibers, and simultaneously reduced the manufacturing costs of respiratory filters. The designed respiratory filters have the potential for application in settings such as hospitals and virus research institutions.

Klíčová slova
Acrylic fibrous waste, Carbon felt, Disinfection, Resistive heating, Respirator filter,
MeSH
dezinfekce metody MeSH
filtrace * přístrojové vybavení metody MeSH
prostředky na ochranu dýchání MeSH
textilie * MeSH
uhlík * chemie MeSH
Publikační typ
časopisecké články MeSH
Názvy látek
uhlík * MeSH

Článek

Aortální a koronární ateroskleróza a nálezy na myokardu pri tyreotoxikóze. Príspevok k práci Z. Erbert, V. Felt
[Aortic anc coronary atherosclerosis and myocardial findings in thyrotoxicosis. Reply to the contribution of Dr. J. Madar]

Casopis lekaru ceskych. 1967 May 12 ; 106 (19) : 515.

Cas Lek Cesk
ISSN 0008-7335
Zdroj

Článek

Impact of Carbon Felt Electrode Pretreatment on Anodic Biofilm Composition in Microbial Electrolysis Cells

Several attempts have been made to improve carbon felt electrode characteristics with various pretreatments ...

Biosensors. 2021 May 26 ; 11 (6) : . [epub] 20210526

Biosensors (Basel)
ISSN 2079-6374
Zdroj

Sustainable technologies for energy production and storage are currently in great demand. Bioelectrochemical systems (BESs) offer promising solutions for both. Several attempts have been made to improve carbon felt electrode characteristics with various pretreatments in order to enhance performance. This study was motivated by gaps in current knowledge of the impact of pretreatments on the enrichment and microbial composition of bioelectrochemical systems. Therefore, electrodes were treated with poly(neutral red), chitosan, or isopropanol in a first step and then fixed in microbial electrolysis cells (MECs). Four MECs consisting of organic substance-degrading bioanodes and methane-producing biocathodes were set up and operated in batch mode by controlling the bioanode at 400 mV vs. Ag/AgCl (3M NaCl). After 1 month of operation, Enterococcus species were dominant microorganisms attached to all bioanodes and independent of electrode pretreatment. However, electrode pretreatments led to a decrease in microbial diversity and the enrichment of specific electroactive genera, according to the type of modification used. The MEC containing isopropanol-treated electrodes achieved the highest performance due to presence of both Enterococcus and Geobacter. The obtained results might help to select suitable electrode pretreatments and support growth conditions for desired electroactive microorganisms, whereby performance of BESs and related applications, such as BES-based biosensors, could be enhanced.