Çimento esaslı kompozitlerde karma lif kullanımı

Öz

İnşaat sektöründeki gelişmelerle birlikte çok yüksek katlı betonarme binaların yaygınlaşması, altyapıya verilen önemin artması, nükleer enerji alanındaki yatırımların söz konusu olması gibi gelişmelerden dolayı beton teknolojisinde lif kullanımı büyük bir önem kazanmıştır. Dolayısıyla, bu lif takviyeli kompozitin özellikle, süneklik özelliğine sahip olması gerektiği açıktır. Lif takviyeli kompozitler yapısal elemanların sünekliğini arttırarak, deprem, roket darbeleri ve patlamalar gibi aşırı deplasman oluşturan olayları esnasında büyük miktarda enerji yutarak ileri düzeyde yapısal göçmeyi engellemek için tasarlanmaktadır. Bu kompozitlerin inşaat sektöründe kullanılmasıyla birlikte, çok yüksek betonarme binaların inşa edilebilmesi, önemli altyapı elemanlarının dayanıklılığının ve ekonomik ömrünün arttırılabilmesi, nükleer enerji santrallerinin güvenliği açısından büyük önem arz eden korunak binalarının daha güvenli yapılabilmesi, betonarme taşıyıcı elemanların kesit ve donatı oranlarında azalmalara gidilebilmesi çok daha mümkün olabilmektedir. Bu bağlamda, beton teknolojisinde yukarıda belirtilen kompozit özelliklerinin sağlanması açısından lif kullanımının önemi artmaktadır. Değişik malzeme özelliklerine sahip lif türlerinin tek veya farklı lif kombinasyonlarıyla birlikte karma olarak kullanımıyla daha gelişmiş kompozitler üretmenin mümkün olduğu yapılan incelemeler sonucunda tespit edilmiştir. Bu makalede, çimento esaslı kompozit üretiminde lif kullanımının önemi, lif tipleri ve kullanım şekilleri (tek lif ve karma lif) ve makro ve mikro lif türlerinin karma lif takviyeli kompozitlerin mühendislik özellikleri üzerine etkileri araştırılmıştır. Sonuçta, çoklu çatlak oluşumu ve yüksek çekme dayanımı gibi avantajları nedeniyle inşaat sektöründe karma lif takviyeli kompozit kullanımı büyük önem kazanmaktadır.

Anahtar Kelimeler

• Çimento esaslı kompozit,Karma lif,Mikro ve makro lif,Süneklik

The use of hybrid in cementitious composites

Abstract

With the developments in the construction sector, the use of fiber in concrete technology has gained great importance due to the developments of the spread of high rise concrete buildings, the increasing importance given to infrastructure, investments in nuclear energy field. Therefore, it is clear that this fiber reinforced composite especially should have also ductility properties. Fiber reinforced composites are designed in order to prevent extremely structural collapse by absorbing massive amount of energy during extreme load-displacement events such as earthquakes, projectile impacts and explosions. It will be much more possible with using this composite in the construction sector to construct much higher concrete building, increase the economic life and strength of important infrastructure members, construct more secure containment buildings which is important for the safety of nuclear power plant, reduce the section and reinforcement ratios in reinforced concrete structural members. In this regard, in the concrete technology in order to provide the above mentioned composite properties, the significance of fiber usage has increased. It was found from studies made that it is possible to produce more developed composites using hybrid fiber having different properties with single or different fiber combinations. In this paper, the significance of the use of fiber for producing the cementitious composite, fiber types and the using forms (single or hybrid) and the effects of micro and macro fiber types on the engineering properties of the hybrid fiber reinforced composites are investigated. Finally, at construction sector the use of hybrid reinforced composites has gained great importance due to the formation of multiple crack and high tensile strength.

Keywords

• Cementitious composite,Hybrid fiber,Micro and macro fiber,Ductility

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