Tekstil ve Mühendis

1300-7599 2147-0510

TMMOB The Chamber of Textile Engineers

10.7216/1300759920182511005

Engineering

Mühendislik

Thickness and Temperature Effects on the Impact Behavior of Glass Fiber Reinforced Polypropylene Composites

Cam Lifi Takviyeli Polipropilen Kompozitlerde Kalınlığın ve Sıcaklığın Darbe Davranışına Etkileri

https://orcid.org/0000-0003-4055-6874

Özdemir

Okan

Kandaş

Halis

06 30 2018

25 110 103 112 11 22 2017 05 10 2018

1987

Journal of Textiles and Engineer

In this study, the low velocity impact behaviors of glass fiber reinforced polypropylene thermoplastic composites were investigated experimentally. In order to improve the low velocity impact behavior, sandwich composites having new orientation were manufactured by using glass fiber reinforced polypropylene composite lamina. Impact tests of composites having thickness of 4 and 6mm were carried out at room temperature and 50˚C so as to investigate the thickness and temperature effects on the low velocity impact behavior. According to the obtained results, maximum contact force of the specimens with two different orientations is enhanced by increasing thickness as it declines by increasing temperature.

Bu çalışmada, uzun cam elyaf takviyeli polipropilen granüllerden oluşan termoplastik kompozitlerin düşük hızlı darbe davranışları deneysel olarak incelenmiştir. Bu kompozitlerin düşük hızlı darbe davranışını iyileştirmek amacıyla cam elyaf takviyeli polipropilen kompozit prepregler kullanılarak sandviç yapıda yeni bir dizilime sahip kompozitler üretilmiştir. Kalınlığın ve sıcaklığın düşük hızlı darbe davranışına olan etkilerini incelemek amacıyla 4 ve 6mm kalınlığa sahip kompozitlerin oda sıcaklığında ve 50˚C’de deneyleri gerçekleştirilmiştir. Elde edilen sonuçlara göre, iki farklı dizilime sahip kompozitlerin kalınlığın artmasıyla maksimum temas kuvvetinin arttığı, sıcaklığın yükselmesiyle ise düştüğü gözlemlenmiştir.

Cam lifi takviyeli polipropilen düşük hızlı darbe kalınlık etkisi sıcaklık etkisi

Glass fiber reinforced polypropylene low velocity impact thickness effect temperature effect

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