Gradient non-woven fabrics with a modified surface nanolayer for water filtration in construction industry

Автор: Victor G. Nazarov, Leonid A. Ivanov, Alexander V. Dedov, Elena S. Bokova, Evgeny S. Statnik

Журнал: Nanotechnologies in Construction: A Scientific Internet-Journal @nanobuild-en

Рубрика: Technologies for production of construction materials and products

Статья в выпуске: 2 Vol.15, 2023 года.

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Introduction. The aim of the work is to determine the influence of the structure of the filter materials formed as a result of modification of the surface layer on their water permeability and the size of trapped solid particles. Materials and methods. The non-woven fabrics from a mixture of polyethylene-terephthalate (PET) (70 wt.%) and bicomponent fibers (BCF) of the coreshell structure were used as objects of the study. The non-woven fabrics were obtained by mechanically forming the canvas with its subsequent hardening by needle punching. The resulting materials were modified by heat treatment. The water transfer in the modified materials was determined by the permeability coefficient. The filtration efficiency was determined by the number of trapped particles of a certain size. Results and discussion. The needle-punched non-woven fabrics without additional heat treatment are not suitable for water filtration. The proposed method of thermal and deformation-thermal modification provides the production of gradient materials with a controlled thickness of the nanoscale surface layer. Although a decrease in water permeability is observed, the modified material traps solid particles with a smaller (compared to unmodified ~ 20 μm) equivalent diameter of 2–4 μm, which is sufficient to prepare water for use in steam generators and in the production of building materials. Conclusion. The optimal parameters of deformation-heat treatment for obtaining the high-effective filtration non-woven materials were established: the temperature – 180оC, the processing speed – 3.5 m/min.

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Needle-punched non-woven fabric, heat treatment, water filtration, filter nanolayer

Короткий адрес: https://sciup.org/142237967

IDR: 142237967   |   DOI: 10.15828/2075-8545-2023-15-2-117-123

Список литературы Gradient non-woven fabrics with a modified surface nanolayer for water filtration in construction industry

  • Patanaik A., Anandjiwala R., Some Studies on Water Permeability of Nonwoven Fabrics. Textile Research J. 2009; 79(2): 147–152.
  • Ozen I. Multi-layered breathable fabric structures with enhanced water resistance. J. Engineered Fibers and Fabrics. 2012; 7(4): 63–69.
  • Kothari V. K., Das A., Singh S., Filtration behavior of woven and nonwoven fabrics. Indian J. Fibre and Textile Research. 2007. V. 32. № 6. P. 214–220.
  • Almanea M.N., Elkhatib E.A., Mahdy A.M. Effects of water treatment residuals on the kinetics of Ni(II) sorption and desorption in some arid soils. Alex. Sci. Exch. J. 2016. 37(2): 287–299
  • Ali F. A study of collapsible behavior of soil blended with fly ash and kota stone dust. Imperial J. Interdisciplinary Res. 2017; 3(2): 446–453.
  • Nikonov E.G., Pavlus M., Popovicova M.2D Microscopic and macroscopic simulation of water and porous material interaction. Computer Research and Modeling. 2018; 10(1): 77–86.
  • Tao F., Valenzuela Garcia A., Xiao T., Chen X., Zhang Y., Yin Y. Interfacial solar vapor generation: introducing students to experimental procedures and analysis for efficiently harvesting energy and generating vapor at the air-water interface. J.Chem. Education. 2020; 97(4): 1093–1100.
  • Qin S., Qian M., Chen T., Yang Q., Xu H., Zheng L., Yao Y. Hierarchical microspheres composed of mn-doped cop nanosheets for enhanced oxygen evolution. ACS Appl. Nano Materials. 2020; 3(11): 10702–10707.
  • Ivanov L.A., Xu L.D., Bokova E.S., Ishkov A.D., Muminova S.R. Inventions of scientists, engineers and specialists from different countries in the area of nanotechnologies. Part I. Nanotechnologies in Construction. 2021; 13(1): 23–31. https://doi.org/10.15828/2075-8545-2021-13-1-23-31
  • Bakhronov K. S. Intensification of the operation of an industrial evaporator. Chem. Petroleum Engineer. 2006; 42 (7): 433–434.
  • Pu L., Qu Z., Bai Y., Qi D., Song K., Yi P. Thermal performance analysis of intermediate fluid vaporizer for liquefied natural gas. Appl. Thermal Engineering. 2014; 65(1): 564–574.
  • Ivanov L.A., Bokova E.S., Muminova S.R., Katuhin L.F. Nanotechnologies: a review of inventions and utility models. Part I. Nanotechnologies in Construction. 2020, Vol. 12, no. 1, pp. 27–33.
  • Ivanov L.A., Xu L.D., Bokova E.S., Ishkov A.D., Borisova O.N. Inventions in the area of nanomaterials and nanotechnologies. Part I. Nanotechnologies in Construction. 2022; 14(1): 18–26.
  • Chidambaram Р.К., Jo Y. M., Kim H. D. Theoretical and computational analyses of LNG evaporator. J. Thermal Sci. 2017; 26 (2): 132–137.
  • Olaoye T.S., Dewsbury M., Kunzel H. A method for establishing a hygrothermally controlled test room for measuring the water vapor resistivity characteristics of construction materials. Energies. 2021; 14(1): 33–45.
  • Dedov A.V., Nazarov V.G. Mechanical characteristical of needlepunch material obtained from a mixture of polyester and polypropylene fibers treated on roll calendar. Fibre Chem. 2011; 43(3): 259–262 .
  • Bokova E.S., Dedov A.V. Mechanical characteristical of needlepunch materials theated with heated air. Fibre Chem. 2012; 44(1): 32–34.
  • Dedov A.V., Nazarov V. G. Mechanical Properties of Composite Materials Based on Latex-Impregnated Needle-Punched Nonwoven Fabrics from Fibers of Different Nature. Inorganic Materials: Appl. Research. 2018; 9(1):47–51.
  • Dedov A. V., Roev B. A., Bobrov V. I., Kulikov G. B., Nazarov V. G. Mechanism of Stretching and Breaking of Needle-Punched Nonwovens. Fibre Chem. 2018; 49(5): 334–337.
  • Nazarov V.G., Doronin F.A., Evdokimov A.G., Dedov A.V. Regulation of the wettability of nonwoven cloth by oxyfluorination to improve its impregnation by latex. Fibre Chem. 2020; 52(2): 109–111.
  • Dedov A.V., Babushkin S.V., Platonov A.V., Kondratov A.P., Nazarov V.G. Sorptive properties of nonwoven materials. Fibre Chem. 2001; 33(5): 56–58.
  • Dedov A.V., Nazarov V.G. Processed Nonwoven Needle punched Materials with Increased Strength. Fibre Chem. 2015; 47(2): 121–125.
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