ÖRGÜNÜN VE İLETKEN ATKI SIKLIĞININ HÜCRELİ ÖRGÜLÜ KUMAŞLARIN ELETROMANYETİK KALKANLAMA ETKİNLİĞİNE ETKİSİ

Year 2013, Volume: 23 Issue: 2, 124 - 135, 01.12.2013

Hakan Özdemir Ahmet Özkurt

Abstract

Bu çalışmada, paslanmaz çelikten özlü iplikler ile farklı atkı sıklıklarında dokunan iletken dimi ve hücreli örgülü kumaşların elektromanyetik kalkanlama etkinliği “free space measurement” tekniği ile yatay anten polarizasyonunda ölçülmüştür. Atkı iplikleri anten polarizasyonuna paralel olacak şekilde yerleştirilen dokuma kumaş numunelerinin endüstriyel, bilimsel ve tıbbi band olan yüksek frekans bandında iyi elektromanyetik kalkanlama performansı gösterdiği gözlenmiştir. Ayrıca çelik özlü atkı ipliklerin sıklığı artırıldığında aynı konumda yerleştirilen kumaş numunelerinin elektromanyetik kalkanlama etkinliğinin arttığı gözlenmiştir. Atkı iplikleri anten polarizasyonuna dik olacak biçimde yerleştirilen kumaş numunelerinin elektromanyetik kalkanlama etkinliği ise efektif yüzey iletkenliğinin artmasına bağlı olarak artış göstermiştir

Keywords

Hücreli örgülü dokuma kumaşlar, Dimi örgü, Elektromanyetik kalkanlama etkinliği, İletken özlü iplikler

THE EFFECTS OF WEAVE AND CONDUCTIVE YARN DENSITY ON THE ELECTROMAGNETIC SHIELDING EFFECTIVENESS OF CELLULAR WOVEN FABRICS

Abstract

In this study, the electromagnetic shielding effectiveness of twill and some cellular woven conductive fabrics woven with stainless steel core yarns at different weft densities has been measured by free space measurement technique at horizontal polarization of the antenna. It is observed that woven fabric samples, which have been positioned so that the weft yarns have been parallel to the antenna polarization, have shown good electromagnetic shielding performances in high frequency band, namely industrial, scientific and medical band. And also, when the steel core weft yarn density has been increased, the decrease in the electromagnetic shielding effectiveness of fabric samples, which have been positioned the same way, is observed. Conversely, the electromagnetic shielding effectiveness of fabric samples, which have been positioned so that the weft yarns have been vertical to the antenna polarization, has increased in agreement with the effective surface conductivity

Keywords

Cellular woven fabrics, Twill weave, Electromagnetic shielding effectiveness, Conductive core yarns

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