Cukurova University,Department of Textile Engineering, Main Branch of Textile Technology

Showing posts with label electromagnetic interference shielding. Show all posts
Showing posts with label electromagnetic interference shielding. Show all posts

October 16, 2019

The effects of metal type, number of layers, and hybrid yarn placement on the absorption and reflection properties in electromagnetic shielding of woven fabrics

In this study, stainless steel, copper, and silver wires were intermingled with two polyamide 6.6 filaments through the commingling technique to produce three-component hybrid yarns. 

The produced hybrid yarns were used as weft in the structure of plain woven fabric samples. 

The electromagnetic shielding effectiveness parameters of samples were measured in the frequency range of 0.8–5.2 GHz by the free space technique. 

The effects of metal hybrid yarn placement, number of fabric layers, metal types, and wave polarization on the electromagnetic shielding effectiveness and absorption and reflection properties of the woven fabrics were analyzed statistically at low and high frequencies separately. 

As a result, the samples have no shielding property in the warp direction. Metal types show no statistically significant effect on electromagnetic shielding effectiveness. 

However, fabrics containing stainless steel have a higher absorption power ratio than copper and silver samples. 

Double-layer samples have higher electromagnetic shielding effectiveness values than single-layer fabrics in both frequency ranges. 

However, the number of layers does not have a significant effect on the absorbed and reflected power in the range of 0.8–2.6 GHz. 

There was a significant difference above 2.6 GHz frequency for absorbed power ratio. 

An increase in the density of hybrid yarns in the fabric structure leads to an increase in the electromagnetic shielding effectiveness values. 

Two-metal placement has a higher absorbed power than the full and onemetal placements, respectively. 

The samples which have double layers and including metal wire were in their all wefts reached the maximum electromagnetic shielding effectiveness values for stainless steel (78.70 dB), copper (72.69 dB), and silver composite (57.50 dB) fabrics.

Source: Journal of Engineered Fibers and Fabrics
Publisher: Association of the Nonwoven Fabrics Industry
Original Language: English
Document type: Article / Open Access



Cited by 12 documents except author up to this time :

Web of Science
1. Akman, F., Ogul, H., Ozkan, I., Kaçal, M. R., Agar, O., Polat, H., & Dilsiz, K. (2022). Study on gamma radiation attenuation and non-ionizing shielding effectiveness of niobium-reinforced novel polymer composite. Nuclear Engineering and Technology, 54(1), 283-292. 

2. Šaravanja, B., Kovačević, S., Pušić, T., Malarić, K., & Ujević, D. (2022). Impact of Dry and Wet Cleaning on Structural, Mechanical and Protective Properties of Fabrics Designed for Electromagnetic Shield Application. Fibers and Polymers, 23(3), 666-679. 

3. Akman, F., Ozkan, I., Kaçal, M. R., Polat, H., Issa, S. A., Tekin, H. O., & Agar, O. (2021). Shielding features, to non-ionizing and ionizing photons, of FeCr-based composites. Applied Radiation and Isotopes, 167, 109470. 

4. Zhang, H., Chen, J., Ji, H., Wang, N., Feng, S., & Xiao, H. (2021). Electromagnetic interference shielding with absorption-dominant performance of Ti3C2TX MXene/non-woven laminated fabrics. Textile Research Journal, 91(21-22), 2448-2458. 

5. You, J. L., Chen, Y. S., Chang, C. P., Wu, M. Z., & Ger, M. D. (2021). Utilizing a pH-responsive palladium nanocomposite to fabricate adhesion-enhanced and highly reliable copper coating on nylon 6 fabrics. Journal of Materials Research and Technology, 15, 3983-3994. 

6. Lou, C. W., Liu, Y. L., Shiu, B. C., Peng, H. K., & Lin, J. H. (2021). Preparation and evaluation of polyester-cotton/wire blended conductive woven fabrics for electromagnetic shielding. Journal of Industrial Textiles, 1528083721997184. 

7. Özkan, İ.(2020). Investigation on the electromagnetic shielding performance of copper plate and copper composite fabrics: A comparative study. Tekstil ve Konfeksiyon, 30(2), 156-162. 

8. Tunakova, V., Tunak, M., Bajzik, V., Ocheretna, L., Arabuli, S., Kyzymchuk, O., & Vlasenko, V. (2020). Hybrid knitted fabric for electromagnetic radiation shielding. Journal of Engineered Fibers and Fabrics, 15, 1-9 

9. İlkan, Ö. (2020). Investigation of the technical and physical properties of metal composite 1× 1 rib knitted fabrics. Industria Textila, 71(1), 41-49. 

10. Liu, X., Yan, X., Su, X., & Song, J. (2020). Study on properties of electromagnetic shielding yarns and fabrics. International Journal of Clothing Science and Technology. 32 (5) , pp.677-690. 

11. Özkan, İ. (2019). Investigation on antimicrobial activity and electromagnetic shielding effectiveness of metal composite single jersey fabrics. Journal of Engineered Fibers and Fabrics, 14, 1558925019895984.

TR Dizin

1. Garip, B., Yüksel, A., Necati, E. R., & Bedeloğlu, A. (2021). Farklı Punta Sayılarının Poliester Kumaş Özellikleri Üzerindeki Etkilerinin İncelenmesi. Konya Mühendislik Bilimleri Dergisi, 9(1), 25-35.
Last Updated: 24.06.2022


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