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Study on Electromagnetic Properties of Graphite/Graphene/Silver-Coated Copper Powder Monolayer Coated Composites

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
With the rapid development of electronic technology and military techniques, electromagnetic protection materials are becoming more and more significant to people. Harmful electromagnetic radiation not only affects the normal operation of electronic equipments and military security, but also has a serious impact on human health. At present, using absorbing and shielding materials are effective means to reduce the harm of electromagnetic waves. In this project, graphite, graphene and silver-coated copper powder coated composites were prepared using PU-2540 polyurethane and adopting a coating process for the substrate on plain polyester/cotton fabric. The controlled variable method was used to prepare and study the electromagnetic properties of single-layer coating composites with different functional particle contents. The result showed that within the frequency range of 0.01GHz~1.0GHz, when the total mass of functional particles was 48% relative to that of the polyurethane, the value of the real part of the dielectric constant of the sample remained the largest and its polarization ability was the strongest. Within the frequency range of 0.08GHz~1.0GHz, when the content of functional particles was 24% relative to that of the polyurethane, the value of the imaginary part of the dielectric constant and the loss of the tangent value of the sample kept the maximum, and the loss and attenuation ability with respect to electromagnetic waves were both the strongest. Within the frequency range of 1.3GHz~2.0GHz, when the content of functional particles was 36% relative to that of the polyurethane, the value of the reflection loss of the sample was -26.93dB, and the minimum value of the reflection loss was obtained at a frequency of 1.6GHz, at the moment of which, the absorbing property of the sample was the best.
Rocznik
Strony
83--90
Opis fizyczny
Bibliogr. 25 poz., rys., tab.
Twórcy
autor
  • Engineering research Center of Technical Textile, Ministry of Education, Donghua University, Shanghai 201620, China
  • School of Textile Science and Engineering, Tiangong University, Tianjin 300387, China
autor
  • School of Textile Science and Engineering, Tiangong University, Tianjin 300387, China
autor
  • School of Textile Science and Engineering, Tiangong University, Tianjin 300387, China
  • School of Textile Science and Engineering, Tiangong University, Tianjin 300387, China
  • School of Textile Science and Engineering, Tiangong University, Tianjin 300387, China
Bibliografia
  • 1. Xiong J, Xiang Z, Zhao J, et al. Layered NiCo alloy nanoparticles/nanoporous carbon composites derived from bimetallic MOFs with enhanced electromagnetic wave absorption performance. CARBON, 2019; 154: 391-401.
  • 2. Liu YJ, Liu YC and Zhao XM. The research of EM wave absorbing properties of ferrite/silicon carbide double coated polyester woven fabric. J TEXT I, 2018; 109(1): 106-112.
  • 3. Liu YJ, Bao WL and Zhao XM. The study on the electromagnetic properties of polyurethane coated pre-oxidized fiber felt composites. J TEXT I, 2020; 112(10): 1596-1601.
  • 4. Liu YJ, Wang Y and Yin G. Preparation of single-layer coating polyester cotton composites with electric loss of their electromagnetic properties. TEXT RES J, 2021; 91(19-20): 2272-2282.
  • 5. Liu YJ, Yu YT and Zhao XM. The influence of the ratio of graphite to silver-coated copper powders on the electromagnetic and mechanical properties of singlelayer coated composites. J TEXT I, 2021; 112(11): 1709-1716.
  • 6. Wang Y, Liu YJ, Yang C, et al. Effect of cobalt ferrite and carbon fiber powder doping ratio on electromagnetic properties of coated polyaniline-based polyestercotton fabric. TEXT RES J, 2022; 92(9-10): 1484-1494.
  • 7. Duan YL, Li Y, Wang DE, et al. Transverse size effect on electromagnetic wave absorption performance of exfoliated thin-layered flake graphite. CARBON, 2019; 153: 682-690.
  • 8. Zhou L, Huang JL, Wang XG, et al. Dielectric properties and electromagnetic interference shielding effectiveness of Al2O3-based composites filled with FeSiAl and flaky graphite. J ALLOY COMPD, 2020; 829: 154556.
  • 9. Zhang X, Qiao J, Wang FL, et al. Tailoring electromagnetic absorption performances of TiO2/Co/carbon nanofibers through tuning graphitization degrees. CERAM INT, 2020; 46(4): 4754-4761.
  • 10. Guan HT and Chung DDL. Radiowave electrical conductivity and absorption-dominant interaction with radio wave of exfoliated-graphite-based flexible graphite, with relevance to electromagnetic shielding and antennas. CARBON, 2020; 157: 549-562.
  • 11. Liu JL, Xu JY, Lu S, et al. Investigation on dielectric properties and microwave heating efficiencies of various concreto pavements during microwave deicing. CONSTR BUILD MATER, 2019; 225: 55-66.
  • 12. Abdalla I, Elhassan A, Yu JY, et al. A hybrid comprised of porous carbon nanofibers and rGO for efficient. Carbon, 2020; 157: 703-713.
  • 13. Fu HL, Yang ZP, Zhang YY, et al. SWCNT-modulated folding-resistant sandwich-structured graphene film for high-performance electromagnetic interference shielding. CARBON, 2020; 162: 490-496.
  • 14. Wang L, Wu Y, Wang Y, et al. Laterally compressed graphene foam/acrylonitrile butadiene styrene composites for electromagnetic interference shielding. COMPOS PART A-APPL S, 2020; 133: 105887.
  • 15. Gao WW, Zhao NF, Yu T, et al. Highefficiency electromagnetic interference shielding realized in nacre-mimetic graphene/polymer composite with extremely low graphene loading. CARBON, 2020; 157: 570-577.
  • 16. Xu YL, Uddin A, Estevez D, et al. Lightweight microwire/graphene/silicone rubber composites for efficient electromagnetic interference shielding and low microwave reflectivity. COMPOS SCI TECHNOL, 2020; 189: 108022.
  • 17. Fan ZM, Wang DL, Yuan Y, et al. A lightweight and conductive MXene/graphene hybrid foam for superior electromagnetic interference shielding. CHEM ENG J, 2020; 381: 122696.
  • 18. Liu Y, Wu YX, Li KX, et al. Amorphous SnS nanosheets/graphene oxide hybrid with efficient dielectric loss to improve the high-frequency electromagnetic wave absorption properties. APPL SURF SCI, 2019; 486: 344-353.
  • 19. Soltani T, Tayyebi A and Lee BK. Efficient promotion of charge separation with reduced graphene oxide (rGO) in BiVO4/rGO photoanode for greatly enhanced photoelectrochemical water splitting. SOL ENERG MAT SOL C, 2018; 185: 325-332.
  • 20. Liu WN, Qiao XJ, Liu S, et al. A new process for pre-treatment of electroless copper plating on the surface of mica powders with ultrasonic and nano-nickel. J ALLOY COMPD, 2019; 791: 613-620.
  • 21. Tardieu S, Mesguich D, Lonjona A, et al. Nanostructured 1% silver-copper composite wires with a high tensile strength and a high electrical conductivity. MAT SCI ENG A-STRUCT, 2019; 761: 138048.
  • 22. Liu YJ, Yu YT and Du HF. The influence of two types of functional particles on the electromagnetic properties and mechanical properties of double-layer coated basalt fiber fabrics. TEXT RES J, 2022; 92(15-16): 2591-2604.
  • 23. Liu YJ and Yang YF. A study on the electromagnetic properties of graphite/bismuth/bismuth oxide-coated composites. TEXT RES J, 2021; 91(17-18): 1986-1998.
  • 24. Liu YJ, Wang Y, Wu X, et al. Preparation and study of electromagnetic properties of graphene/graphite/bismuth oxide threelayer coated textile materials. TEXT RES J, 2021; 91(17-18): 1999-2014.
  • 25. Cheng HR, Wei SN, Ji YX, et al. Synergetic effect of Fe3O4 nanoparticles and carbon on flexible poly (vinylidene fluoride) based films with higher heat dissipation to improve electromagnetic shielding. COMPOS PART A-APPL S, 2019; 121: 139-148.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-dfa017fb-670a-4202-a744-a5a4805ff694
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