Karbon Nanotüp ve Nanokil Takviyesinin Epoksi Karbon Kumaş Kompozit Boruların Mekanik Özelliklerine Etkisinin İncelenmesi

Year 2021, Issue: 28, 198 - 206, 30.11.2021

Bülent Karaoğlu , Hüseyin Arıkan , Mehmet Kayrıcı

https://doi.org/10.31590/ejosat.995135

Cited By: 1

Abstract

Genel olarak nano dolgular, fiber takviyeli polimer esaslı kompozitlerin mekanik ve darbe davranışlarını arttırır. Bununla birlikte, nano dolgu maddelerinin hibridizasyona etkileri ve bunların nano ölçekli hasar mekanizmaları üzerindeki nedenleri, kumaş takviyeli kompozitler için yeterince çalışılmamıştır. Bu çalışmada karbon nanotüpler, nanokil partikülleri takviyeli epoksi karbon kumaş kompozit boruların düşük hızlı darbe tepkileri ve mekanik özellikleri değerlendirilmiştir. Karbon kumaş kompozit borular, ağırlıkça %1 ve 3 karbon nanotüp ve ağırlıkça %1 ve 3 nanokil parçacıkları ve nano madde dolgusuz olarak, elle yatırma tekniği kullanılarak hazırlanmıştır. Karbon nanotüp (MWCNT), nanokil takviyeli epoksi karbon kumaş kompozit borular için düşük hız darbe etkileri ve mekanik özellikleri, nanodolgu partiküllerin içeriğinin bir fonksiyonu olarak elde edilmiştir. ASTM D7136 / D7136 M-12 standartlarına göre 5 J, 10 J ve 15 J enerji seviyeleri için kompozit borulara düşük hızlı darbe testleri uygulanmıştır. 5J, 10 J ve 15 J için Karbon Kumaş/Epoksi’ye ilave edilen karbon nanotüpler (MWCNT) ve nanokil nanodolgularının, maksimum kuvvet, emilen enerji ve en düşük yer değiştirme ve geri tepme enerjisi gösterdiği gözlendi. Karbon Kumaş/Epoksi’ye ,MWCNT ve nanokil gibi nanohibrit ilavesi ise nano dolgu maddesi ilavesi olmayandan, daha yüksek düşük hızlı darbe tepkileri oluşturdu. Nano dolgu maddeleri eklenmemiş Karbon Kumaş/Epoksi kompozit örnekleri, en düşük maksimum kuvvet, en yüksek yer değiştirmeleri ve geri tepme enerjisini gösterdi. Sonuçlar, Karbon Kumaş/Epoksi kompozit borular ile karbon nanotüp (MWCNT) ve nanokil parçacık- larının artmasıyla mekanik özelliklerin önemli ölçüde arttığını göstermektedir.

Keywords

kompozit boru, kumaş, karbon nano tube, imalat, darbe

Supporting Institution

Necmettin Erbakan Üniversitesi Bilimsel Araştırmalar Koordinasyon Başkanlığı

Project Number

181431003

Thanks

Necmettin Erbakan Üniversitesi Bilimsel Araştırmalar Koordinasyon Başkanlığı

Effect of Mechanical Properties on Carbon Nanotubes, Nanoclays Reinforced Epoxy Carbon Fabric Composite Pipes

Abstract

Generally, the nanofillers increase the mechanical and impact behaviors of fiber reinforced polymer based composites. However, the effects of the hybridization of nanofillers and their reasons over the nano scale damage mechanisms have not been adequately studied for fabric reinforced composites. The low velocity impact responses and mechanical properties of carbon nanotubes, nanoclays particles reinforced epoxy carbon fabric composite pipes have been evaluated in this study. Carbon fabric composite pipes have been prepared with 1 ,and 3 wt % of carbon nanotube and 1,and 3 wt% of nanoclay particles and unfilled nanofillers, using hand lay-up technique. Mechanical properties of low velocity impact for carbon nanotubes (MWCNT), nanoclays particles reinforced epoxy carbon fabric composite pipes have been obtained as a function of content of nanofillers particles. The low-velocity impact tests applied on composite pipes for energy levels 5 J,10 J, and 15 J according to in accordance with ASTM D7136 / D7136 M-12 standards. It was observed that carbon nanotubes (MWCNT) and nanoclay nanofillers addition to Carbon Fabric/Epoxy for 5J, 10 J and 15 J showed maximum force, absorbed energy and the lowest displacements and rebound energy. MWCNTs and nanoclays nano-hybrid addition to Carbon Fabric/Epoxy improved higher low velocity impact responses than none nanofillers addition. The specimens of unfilled nanofillers Carbon Fabric/Epoxy composites showed the lowest maximum force , highest displacements and rebound energy. The results show that the mechanical properties are found to increase substantially with increasing carbon nanotube (MWCNT) and nanoclays particles with Carbon Fabric/Epoxy composite pipes.

Keywords

composite pipe, fabric, carbon nanotube, impact, fabrication

Project Number

181431003

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