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Abstrak
ABSTRAK
Pada penelitian ini telah dikembangkan sebuah produk pakaian anti radiasi unisex sports wear menggunakan teknologi plasma pijar korona elektroda tip-plane. Plasma pijar korona dibangkitkan dengan listrik tegangan tinggi serta menggunakan elektroda asimetri (lancip dan plat).Pembuatan pakaian anti radiasi menggunakan bahan rajut yang telah diplasma sertadilapisi dengan tinta konduktif. Hasil studi memperlihatkan bahwa metode pembuatan pakaian dengan plasma pijar korona telah berhasil mengurangi radiasi gelombang elektromagnetik.
Kata kunci: plasma pijar, pakaian unisex sportswear, elektroda tip-plane, anti radiasi
ABSTRACT
This paper describes the making of an anti-radiation smartphone unisex sportswear. The anti-radiation patch was developed by first modifiying the surface of the textile using atmospheric pressure plasma technology. The plasma corona discharge is generated by using a high voltage electricity withasymmetrical electrodes (tip and plane). The treated patch was than coated with graphite based conductive ink. The result of thisresearchindicates that an anti-radiation clothe patch was succesfully shield an electromagnetic radiation from a smartphone.
Keywords: plasma discharge, unisex sportswear, tip-plane electrode, electromagnetic shielding
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Referensi
- Shishoo, 2007, Plasma Technology For Textile, Woodhead Publishing, Cambridge.
- Usman, A.S, 2012,Peningkatan Daya Saing Industri TPT Melalui Standarisasi, Makalah Seminar Nasional Tekstil, Bandung.
- Yales, V. Kendalikan Konsumsi Energi Sektor Manufaktur. Surat Kabar KOMPAS, 18 April 2012, halaman 7
- Sjaifudin dan KH Sitohang, 2015, Rancang Bangun Prototip Mesin Plasma Tekstil Lucutan Korona pada Tekanan Atmosfir Skala Laboratorium, Balai Besar Tekstil, Bandung.
- Sjaifudin, Widodo, M., Muhlisin, Z., Nur, M, 2014,Modifikasi PermukaanBahanTekstil dengan Plasma Lucutan Korona, Prosiding Seminar Nasional Tekstil, 1-22.
- Rauscher, Perucca, Buyle, 2010, Plasma Technology for Hyperfunctionals Surfaces, Wiley-VCH, Weinheim.
- Lawrence, C A 2003, Fundamentals of Spun Yarn Technology, CRC Press, New York.
- Putra VGV, Dewanto A, Totong, 2016, Predicting Non Inertia Frame Related By Speed of Bobbin Compared by Speed of Rotor, Global Journal of Pure and Applied Mathematics, Vol 12.,No.5 pp. 4107-4114.
- Putra VGV, Maruto, G &Rosyid, M.F, 2017, New theoretical modeling for predicting yarn angle on OE yarn influenced by fibre movement on torus coordinate based on classical mechanics approach, Indian Journal of Fibre and Textile Research, Vol.42. pp. 359-363.
- M. Lieberman and A. Lichtenberg, 1994, Principles of Plasma Discharges and Materials Processing, John Wiley and Sons, New York.
- Boonchoat Paosawatyanyong, Satreerat Hodak, 2010, Hydrophobic and Hydrophilic Surface Nano-Modification of PET Fabric by Plasma Process, Journal of Nanoscience and Nanotechnology, Vol. 10, pp 7050–7054
- Safarova, V.; Tunak, M.; Truhlar, M.; Militky, J., 2016 A new method and apparatus for evaluating the electromagnetic shielding effectiveness of textiles.Text. Res. J., 86, 44–56
- Chen, H.C.; Lee, K.C.; Lin, J.H.; Koch, M, 2007,Comparison of electromagnetic shielding effectiveness properties of diverse conductive textiles via various measurement techniques. J. Mater. Process Techol. 192, 549–554
- Safarova, V.; Militky, J., 2012, Comparison of methods for evaluating the electromagnetic shielding of textiles. Fibers Text. 19, 50–55.
- Avloni, J.; Lau, R.; Ouyang, M.; Florio, L.; Henn, A.R.; Sparavigna, A, 2007, Shielding Effectiveness Evaluation of Metallized and Polypyrrole-Coated Fabrics.J. Thermoplast. Comp. Mater. 20, 241–254.
- Ozen, M.S.; Usta, I.; Yuksek, M.; Sancak, E.; Soin, N., 2018 Investigation of the Electromagnetic Shielding Effectiveness of Needle Punched Nonwoven Fabrics Produced from Stainless Steel and Carbon Fibres. Fibers Text.East. Eur.26, 94–100.
- MarComm, M., 2018, MILLENIALS, Fantasious x Loveable, Jakarta.
- Stillman, D. S., 2018,Generasi Z: Memahami Karakter Generasi Baru yang Akan Mengubah Dunia Kerja, PT Gramedia Pustaka Utama, Jakarta.
Referensi
Shishoo, 2007, Plasma Technology For Textile, Woodhead Publishing, Cambridge.
Usman, A.S, 2012,Peningkatan Daya Saing Industri TPT Melalui Standarisasi, Makalah Seminar Nasional Tekstil, Bandung.
Yales, V. Kendalikan Konsumsi Energi Sektor Manufaktur. Surat Kabar KOMPAS, 18 April 2012, halaman 7
Sjaifudin dan KH Sitohang, 2015, Rancang Bangun Prototip Mesin Plasma Tekstil Lucutan Korona pada Tekanan Atmosfir Skala Laboratorium, Balai Besar Tekstil, Bandung.
Sjaifudin, Widodo, M., Muhlisin, Z., Nur, M, 2014,Modifikasi PermukaanBahanTekstil dengan Plasma Lucutan Korona, Prosiding Seminar Nasional Tekstil, 1-22.
Rauscher, Perucca, Buyle, 2010, Plasma Technology for Hyperfunctionals Surfaces, Wiley-VCH, Weinheim.
Lawrence, C A 2003, Fundamentals of Spun Yarn Technology, CRC Press, New York.
Putra VGV, Dewanto A, Totong, 2016, Predicting Non Inertia Frame Related By Speed of Bobbin Compared by Speed of Rotor, Global Journal of Pure and Applied Mathematics, Vol 12.,No.5 pp. 4107-4114.
Putra VGV, Maruto, G &Rosyid, M.F, 2017, New theoretical modeling for predicting yarn angle on OE yarn influenced by fibre movement on torus coordinate based on classical mechanics approach, Indian Journal of Fibre and Textile Research, Vol.42. pp. 359-363.
M. Lieberman and A. Lichtenberg, 1994, Principles of Plasma Discharges and Materials Processing, John Wiley and Sons, New York.
Boonchoat Paosawatyanyong, Satreerat Hodak, 2010, Hydrophobic and Hydrophilic Surface Nano-Modification of PET Fabric by Plasma Process, Journal of Nanoscience and Nanotechnology, Vol. 10, pp 7050–7054
Safarova, V.; Tunak, M.; Truhlar, M.; Militky, J., 2016 A new method and apparatus for evaluating the electromagnetic shielding effectiveness of textiles.Text. Res. J., 86, 44–56
Chen, H.C.; Lee, K.C.; Lin, J.H.; Koch, M, 2007,Comparison of electromagnetic shielding effectiveness properties of diverse conductive textiles via various measurement techniques. J. Mater. Process Techol. 192, 549–554
Safarova, V.; Militky, J., 2012, Comparison of methods for evaluating the electromagnetic shielding of textiles. Fibers Text. 19, 50–55.
Avloni, J.; Lau, R.; Ouyang, M.; Florio, L.; Henn, A.R.; Sparavigna, A, 2007, Shielding Effectiveness Evaluation of Metallized and Polypyrrole-Coated Fabrics.J. Thermoplast. Comp. Mater. 20, 241–254.
Ozen, M.S.; Usta, I.; Yuksek, M.; Sancak, E.; Soin, N., 2018 Investigation of the Electromagnetic Shielding Effectiveness of Needle Punched Nonwoven Fabrics Produced from Stainless Steel and Carbon Fibres. Fibers Text.East. Eur.26, 94–100.
MarComm, M., 2018, MILLENIALS, Fantasious x Loveable, Jakarta.
Stillman, D. S., 2018,Generasi Z: Memahami Karakter Generasi Baru yang Akan Mengubah Dunia Kerja, PT Gramedia Pustaka Utama, Jakarta.