Silika esaslı kayma ile kalınlaşan sıvı emdirilmiş aramid kumaşların darbe ve balistik performansları

Year 2021, Volume: 10 Issue: 2, 847 - 854, 27.07.2021

Oylum Çolpankan Güneş , Sema Yıldız Mehmet Güneş Fikret Şenel Metin Tanoglu

https://doi.org/10.28948/ngumuh.833741

Abstract

Bu çalışma, kayma ile kalınlaşan sıvılar (KKSler) ile işlem görmüş gelişmiş bıçak ve balistik dirençlere sahip aramid kumaş üretimine odaklanmaktadır. KKSler, PEG ve etil alkol içinde silika parçacıklarının homojenleştirilmesi, kurutma ve öğütme aşamaları ile hazırlanmıştır. Reolojik ölçümler, silika nanopartiküllerin PEG'e eklenmesinin, kayma ile kalınlaşma davranışını arttığını göstermiştir. Silika konsantrasyonu arttıkça, partiküller arası kuvvetler artmakta ve bu da partiküller arasındaki sürtünmeyi büyük ölçüde arttıarak KKSlerin gelişmiş bir kayma ile kalınlaştırma özelliğine neden olmaktadır. Yarı statik ve dinamik bıçak direnç testleri, artan kayma ile kalınlaşma tepkisinin, KKS/ aramid hedeflerinde ham aramid kumaşa göre artan bıçak performansına karşılık geldiğini göstermiştir. Balistik test sonuçları, ham aramid kumaş ve STF/aramid hedefler arasındaki balistik dirençte artış olduğunu göstermiştir. Ayrıca, STF/aramid hedeflerin esnekliğinin de ham aramid kumaşa göre önemli bir ölçüde azalmadığı da görülmüştür.

Keywords

Aramid kumaş, Kayma ile kalınlaşan sıvılar, Darbe direnci, Reoloji, Balistik performans

Stab and ballistic performances of aramid fabrics impregnated with silica based shear thickening fluids

Abstract

This study focuses on the production of aramid fabric with improved stab and ballistic resistances treated with shear thickening fluids (STFs). The STFs were prepared by homogenization of various amount of silica particles within the PEG and ethyl alcohol, drying, and grinding steps. The rheological measurements showed that the addition of silica nanoparticles into the PEG, shear thickening behavior was enhanced. As silica concentration increased, the interparticle forces increased and so the friction between particles greatly increased, causing an enhanced shear-thickening property. Quasi-static and dynamic stab resistance tests showed that increasing shear thickening response corresponded to increased stab performance in the STF/aramid targets as compared to untreated aramid fabric. Ballistic test results showed that there was an increment in the ballistic resistance between untreated fabric and STF/aramid composites. It was also found that the flexibility of STF/aramid targets did not decrease significantly compared to the untreated aramid fabric.

Keywords

Aramid fabric, Shear thickening fluids, Stab resistance, Rheology, Ballistic performance

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