Tekerlek Ray Etkileşimi, Perlitik ve Beynitik Çeliklerin Yorulma Hasar Direnci Üzerine Bir Sonlu Elemanlar Analizi

Year 2021, Issue: 14, 65 - 76, 31.07.2021

Yasin Sarıkavak

https://doi.org/10.47072/demiryolu.934471

Cited By: 3

Abstract

Bu çalışmada ülkemizde ve dünyada demiryolu hatlarında işletme şartlarında çoğunlukla kullanımda olan perlitik mikroyapıdaki çelikler ve perlitik çeliklere alternatif olarak sunulan, gelişmiş mekanik özelliklere sahip olan beynitik mikroyapıdaki çelikler ele alınmıştır. Geniş bir literatür özetiyle konvansiyonel ray sınıfları ve gelişmiş ray sınıfları, kimyasal kompozisyonları ve temel mekanik özellikleri dikkate alınarak değerlendirilmiştir. Ayrıca dünyada farklı bölge ve ülkelerde geliştirilen beynitik ray çelikleri incelenmiştir. Daha sonra tekerlek ray etkileşimi, sürtünme şartları ve temas yüzeyleri dikkate alınarak, geliştirilen sonlu elemanlar modelinde rayın yorulma hasar direnci analiz edilmiştir. Sonuç olarak analiz edilen beynitik mikroyapıdaki çeliğin yorulma hasar direncinin perlitik mikroyapıya göre üstün olduğu ve 386,69 MPa yük altında on milyon çevrime dayanabildiği anlaşılmıştır.

Keywords

Çelik yapılar, Demiryolu malzemeleri, Tekerlek-ray etkileşimi, Yorulma hasarı, Sonlu elemanlar analizi

Supporting Institution

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Project Number

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Thanks

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Wheel Rail Interaction and a Finite Element Analysis on Fatigue Failure Resistance of Pearlitic and Bainitic Steels

Abstract

In this study, pearlitic microstructure steels, which are frequently used in the operational conditions of railways, and alternatively developed, bainitic microstructure steels, that has advanced mechanical properties are investigated. Conventional and advanced rail grades were investigated in terms of chemical composition and mechanical properties with an extended literature review. In addition, bainitic rail steels developed in different regions and countries were analyzed. Fatigue failure resistance of rails were analyzed with finite element method considering wheel-rail interaction, friction parameters and contact regions. In conclusion, analyzed bainitic microstructure shows advanced fatigue characteristics than pearlitic microstructure with ten million cycle resistance under 386.9 MPa load.

Keywords

Steel structures, Railway materials, Wheel-rail interaction, Fatigue failure, Finite element analysis

Project Number

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