Three Point Bending Behavior of Woven Glass, Aramid and Carbon Fiber Reinforced Hybrid Composite Tube

• Authors: S. Ekşi , K. Genel
• Languages of publication: EN

Abstracts

EN

In this study, bending behavior of hybrid composites reinforced by different type of fibers is investigated experimentally. In the preparation of composite samples with different number of layers having the same thickness and woven shaped glass, aramid and carbon fibers are used and three-point bending test is carried out to determine bending behavior. It is seen from the test results that, regardless of fiber type, the load bearing capacity and energy absorption capability are increased by increasing layer number. As a result of evaluation of hybrid composites containing different fibers with respect of load-carrying capability and energy absorbing capacity, aramid-fiber reinforced composite with 2 and 4 layer provides better performance. T+2GF+2CF+2AF specimen can be preferred in between 10 layered hybrid tubes and T+2GF+2AF+6CF and T+2GF+2CF+6AF specimens in 10 layered hybrid tubes. Load carrying capacity of hybrid tubes increased 7 times and energy absorbing capacity 9.6 times, respectively.

Keywords

EN

62.20.M-; 62.20.mq; 62.23.Pq

Discipline

• 62.23.Pq: Composites (nanosystems embedded in a larger structure)
• 62.20.mq: Buckling
• 62.20.M-: Structural failure of materials(for materials treatment effects on microstructure, see 81.40.Np)

• Publisher: Institute of Physics, Polish Academy of Sciences
• Journal: Acta Physica Polonica A
• Year: 2015
• Volume: 128
• Issue: 2B
• Pages: B-59-B-61

Dates

published

2015-8

Contributors

author

S. Ekşi

• Sakarya University, Mechanical Engineering Department, Sakarya, Turkey

author

K. Genel

• Sakarya University, Mechanical Engineering Department, Sakarya, Turkey

References

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Identifiers

DOI

10.12693/APhysPolA.128.B-59