Publication:
Basalt fiber reinforced foam concrete with marble waste and calcium aluminate cement

dc.contributor.authorBayraktar O.Y., Yarar G., Benli A., Kaplan G., Gencel O., Sutcu M., Kozłowski M., Kadela M.
dc.contributor.authorBayraktar, OY, Yarar, G, Benli, A, Kaplan, G, Gencel, O, Sutcu, M, Kozlowski, M, Kadela, M
dc.date.accessioned2023-05-09T15:31:25Z
dc.date.available2023-05-09T15:31:25Z
dc.date.issued2023-02-01
dc.date.issued2022.01.01
dc.description.abstractAs a typical cellular lightweight material, foam concrete is produced by mixing cement, water, aggregate and a suitable foaming agent and has a density usually below 1600 kg/m3. The large number of air spaces present in foam concrete ensures that the concrete has advantages such as lightweight, high fluidity during pouring, excellent thermal and sound insulation, superior fire resistance, and outstanding energy absorption capacity. Its high porosity and the connectivity of the pores, which can allow the entry of negative substances into the concrete environment, cause foam concrete to have a very low physico-mechanical and durability performance. To eliminate or reduce these disadvantages, this study adopted the use of basalt fibers (BF) as eco-friendly fiber type and calcium aluminate cement (CAC) as aluminous cement with waste marble powder (WMP) as aggregates in foam concrete. In that respect, 9 mixes with varying content of foaming agent (FC) and basalt fiber have been prepared. Assessment of mechanical performance was based on compressive and flexural strength after 6 h, 1, 7, and 28 days. Dry bulk density, thermal conductivity, porosity, water absorption, and sorptivity of the concretes were determined. Durability characteristics of the concretes were examined by dry shrinkage, high temperature, magnesium sulfate, sulfuric, and hydrochloric acids. The obtained results showed that the content of BF affected the compressive strength of the mixtures slightly negatively or positively depending on the FC. The lowest value in thermal conductivity was gained as 0.645 (W/m K) for the mixture incorporating 1% BF and 50 kg/m3 foam quantity. In addition, the foam concrete incorporating foam of 30 kg/m3 and 1% BF showed the best resistance against MgSO4. The mixture with 2% BF and 30 kg/m3 FC exhibited the lowest mass loss after HCI exposure.
dc.identifier.doi10.1002/suco.202200142
dc.identifier.eissn1751-7648
dc.identifier.issn1464-4177
dc.identifier.scopus2-s2.0-85131766244
dc.identifier.urihttps://hdl.handle.net/20.500.12597/12375
dc.identifier.wosWOS:000810577800001
dc.relation.ispartofStructural Concrete
dc.relation.ispartofSTRUCTURAL CONCRETE
dc.rightsfalse
dc.subjectbasalt fiber | calcium aluminate cement | durability | foam concrete | mechanical properties | waste marble powder
dc.titleBasalt fiber reinforced foam concrete with marble waste and calcium aluminate cement
dc.titleBasalt fiber reinforced foam concrete with marble waste and calcium aluminate cement
dc.typeArticle
dspace.entity.typePublication
oaire.citation.issue1
oaire.citation.volume24
relation.isScopusOfPublicationae1b9a77-79de-47d5-83a0-fabdacc20b12
relation.isScopusOfPublication.latestForDiscoveryae1b9a77-79de-47d5-83a0-fabdacc20b12
relation.isWosOfPublicationed84dea0-6a21-46e8-98dc-126742bc4178
relation.isWosOfPublication.latestForDiscoveryed84dea0-6a21-46e8-98dc-126742bc4178

Files

Collections