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Basalt fiber-reinforced foam concrete containing silica fume: An experimental study

[Display omitted] •The addition of basalt fiber enhances mechanical properties while it also increases the porosity and water absorption values of foam concrete.•Higher content of foaming agent enhances insulating properties but reduces physico-mechanical properties.•Silica fume is found most effect...

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Bibliographic Details
Published in:Construction & building materials 2022-04, Vol.326, p.126861, Article 126861
Main Authors: Gencel, Osman, Nodehi, Mehrab, Yavuz Bayraktar, Oguzhan, Kaplan, Gokhan, Benli, Ahmet, Gholampour, Aliakbar, Ozbakkaloglu, Togay
Format: Article
Language:English
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Summary:[Display omitted] •The addition of basalt fiber enhances mechanical properties while it also increases the porosity and water absorption values of foam concrete.•Higher content of foaming agent enhances insulating properties but reduces physico-mechanical properties.•Silica fume is found most effective in reducing the adverse effects of freeze thawing and high temperature exposure. Foam concrete refers to a type of low-density concrete that is commonly known to have favorable insulation and thermal performance due to its intentionally increased porosity. However, foam concrete is known to generally have a very low physico-mechanical and durability performance mainly due to its high porosity and the connectivity of the pores that can allow the entrance of unfavorable substances into the concrete medium. As a result, most often, foam concrete is considered inapplicable to major load bearing structural elements. To counter this tendency, this study adopted the use of basalt fibers with silica fume to increase the structural integrity of foam concrete. In that respect, 18 mixes with varying content of foaming agent, basalt fiber and silica fume have been prepared. Apparent porosity, water absorption, compressive, flexural and splitting tensile strength, sorptivity, ultrasonic pulse velocity (UPV), drying shrinkage, freeze–thaw, thermal conductivity, and thermal resistance tests were performed to evaluate the physico-mechanical, durability, and insulation properties of the produced foam concretes. Based on the results, a highly durable foam concrete with a maximum compressive, flexural and splitting tensile strength of ∼ 46, 6.9 and 3.07 MPa, respectively, has been developed. Furthermore, it is observed that the inclusion of silica fume can significantly influence the pore network and enhance fiber-paste matrix. The effect of basalt fiber, however, is found to be more dependent on the use of silica fume, potentially due to its low integration with cementitious paste. The results of this study are significant and point out to the great potential for producing a highly durable and lightweight insulating foam concrete through the use of basalt fiber and silica fume.
ISSN:0950-0618
1879-0526
DOI:10.1016/j.conbuildmat.2022.126861