Çimento Esaslı Kompozitlerde Çatlak Oluşumu ve Çatlak Kontrolünde Lif Kullanımının ve Karışım Parametrelerinin Etkisi: Derleme

Year 2024, , 422 - 436, 01.03.2024

Berfin Ramazanoğlu , Necim Kaya

https://doi.org/10.21597/jist.1342361

Abstract

Beton, yüksek basınç dayanımlarını karşılayabilmesine rağmen doğası gereği çekme ve eğilme dayanımı düşük olduğundan çatlak oluşumuna karşı hassas bir yapı malzemesidir. Beton, çok fazlı kompozit bir malzeme olup, davranışı kendisini oluşturan bileşenlerin özelliklerine göre değişkenlik göstermektedir. Her bir karışım parametresinin çatlak gelişim mekanizması üzerinde önemli etkileri bulunmaktadır. Mevcut derleme çalışmasında çimento esaslı malzemelerde çatlak gelişim mekanizması ve karışım parametrelerinin çatlak oluşum mekanizması üzerine olan etkileri özellikle son 10 yılda yapılan çalışmalar esas alınarak geniş bir literatür taramasıyla araştırılmıştır. Literatür araştırması sonucunda, düşük su/çimento oranı, parçacık boyutu dağılımı ve karışım oranlarının optimize edilmesiyle maksimum agrega parçacık yoğunluğunun elde edilmesi, çimentonun bir kısmının optimum miktarda mineral katkılar ve nano malzemelerle değiştirilmesi, gevrek özellik gösteren çimento matrisinin çeşitli liflerle hibrit kombinasyonun, betonun dayanımını, sünekliğini ve tokluğunu iyileştirerek çatlak oluşumuna karşı dayanımı arttırdığı anlaşılmıştır.

Keywords

Beton, Beton bileşenleri, Çatlak gelişimi, Dayanım

Effect of Fiber Usage and Mixture Parameters on Crack Development and Crack Control in Cement Based Composites: Review

Abstract

Although concrete can meet high compressive strength, it is a building material that is sensitive to crack formation due to its inherently low tensile and bending strength. Concrete is a multi-phase composite material, and its behavior varies depending on the properties of the components that make it up. Each mixture parameter has significant effects on the crack development mechanism. In the current review study, the crack development mechanism in cement-based materials and the effects of mixture parameters on the crack formation mechanism were investigated with an extensive literature review, especially based on the studies carried out in the last 10 years. As a result of the literature research, obtaining maximum aggregate particle density by optimizing low water/cement ratio, particle size distribution and mixture ratios, replacing some of the cement with optimum amount of mineral additives and nano materials, hybrid combination of brittle cement matrix with various fibers, increasing the strength of concrete, It has been understood that it increases the resistance against crack formation by improving its ductility and toughness.

Keywords

Concete, Concrete components, Crack development, Strength

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