This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Erdem T.K., Turanlı L., Erdoğan T.Y. (2005). Setting time: An important criterion to determine the length of the delay period before steam curing of concrete. Cement and Concrete Research 33, 741–745.ErdemT.K.TuranlıL.ErdoğanT.Y.2005Setting time: An important criterion to determine the length of the delay period before steam curing of concreteCement and Concrete Research3374174510.1016/S0008-8846(02)01058-XSearch in Google Scholar
TS EN 3648:1984. Steam Curing of Precast Concrete Products Under Atmospheric Pressure, Standard.TS EN 3648:1984Steam Curing of Precast Concrete Products Under Atmospheric Pressure, StandardSearch in Google Scholar
Vollenweider B. (2004). Various Methods of Accelerated Curing for Precast Concrete Applications, and Their Impact on Short and Long-Term Compressive Strength. Concrete Technology CE 241.VollenweiderB.2004Various Methods of Accelerated Curing for Precast Concrete Applications, and Their Impact on Short and Long-Term Compressive Strength. Concrete Technology CE 241Search in Google Scholar
Müller C. (2009). Resource efficiency in the production of cement and concrete. VDZ Congress, Resource Initiative – Leveraging efficiency to meet India’s needs, New Delhi.MüllerC.2009Resource efficiency in the production of cement and concreteVDZ Congress, Resource Initiative – Leveraging efficiency to meet India’s needsNew DelhiSearch in Google Scholar
Türkel S., Alabas V. (2005). The effect of excessive steam curing on Portland composite cement concrete. Cement and Concrete Research 35, 405–411.TürkelS.AlabasV.2005The effect of excessive steam curing on Portland composite cement concreteCement and Concrete Research3540541110.1016/j.cemconres.2004.07.038Search in Google Scholar
Liu B., Xie Y., Li J. (2005). Influence of steam curing on the compressive strength of concrete containing supplementary cementing materials. Cement and Concrete Research 35, 994–998.LiuB.XieY.LiJ.2005Influence of steam curing on the compressive strength of concrete containing supplementary cementing materialsCement and Concrete Research3599499810.1016/j.cemconres.2004.05.044Search in Google Scholar
García Calvo J.L., Alonso M.C., Fernández Luco L., Robles Velasco M. (2016). Durability performance of sustainable self-compacting concretes in precast products due to heat curing. Construction and Building Materials, 379-38.García CalvoJ.L.AlonsoM.C.Fernández LucoL.Robles VelascoM.2016Durability performance of sustainable self-compacting concretes in precast products due to heat curingConstruction and Building Materials3793810.1016/j.conbuildmat.2016.02.097Search in Google Scholar
Gonzalez-Corominas A., Etxeberria M., Poon C.S. (2016). Influence of steam curing on the pore structures and mechanical properties of fly-ash high-performance concrete prepared with recycled aggregates. Cement and Concrete Composites, 71–784.Gonzalez-CorominasA.EtxeberriaM.PoonC.S.2016Influence of steam curing on the pore structures and mechanical properties of fly-ash high-performance concrete prepared with recycled aggregatesCement and Concrete Composites7178410.1016/j.cemconcomp.2016.05.010Search in Google Scholar
Arel H. Ş. (2016). Effects of curing type, silica fume fineness, and fiber length on the mechanical properties and impact resistance of UHPFRC, Results in Physics 6; 664–674.ArelH. Ş.2016Effects of curing type, silica fume fineness, and fiber length on the mechanical properties and impact resistance of UHPFRCResults in Physics666467410.1016/j.rinp.2016.09.016Search in Google Scholar
Marcos-Meson V., Fischer G., Edvardsen C., Michel Durability A. (2018). Durability of steel fibre reinforced concrete (SFRC) exposed to acid attack – a literature review, Construction and Building Materials, 200; 490–501.Marcos-MesonV.FischerG.EdvardsenC.Michel DurabilityA.2018Durability of steel fibre reinforced concrete (SFRC) exposed to acid attack – a literature reviewConstruction and Building Materials20049050110.1016/j.conbuildmat.2018.12.051Search in Google Scholar
ACI Committee 544:2009 544.1R-96: Report on Fiber Reinforced Concrete (Reapproved 2009).ACI Committee 544:2009 544.1R-96: Report on Fiber Reinforced Concrete (Reapproved 2009)Search in Google Scholar
Wang Z., Shi Z., Wang, J. (2011). On the Strength and Toughness Properties of SFRC Under Static-dynamic Compression, Composites: Part B Engineering 42(5) 1285–1290.WangZ.ShiZ.WangJ.2011On the Strength and Toughness Properties of SFRC Under Static-dynamic CompressionComposites: Part B Engineering4251285129010.1016/j.compositesb.2011.01.027Search in Google Scholar
Wu., H. Lin., X Zho., A. (2020). A review of mechanical properties of fibre reinforced concrete at elevated temperatures. Cement and Concrete Research, 135, 106117.Wu.H.Lin.XZho.A.2020A review of mechanical properties of fibre reinforced concrete at elevated temperaturesCement and Concrete Research13510611710.1016/j.cemconres.2020.106117Search in Google Scholar
Xu B., Shi, H. (2009). Correlations Among Mechanical Properties of Steel Fiber Reinforced Concrete, Construction and Building Materials 23(12), 3468–3474.XuB.ShiH.2009Correlations Among Mechanical Properties of Steel Fiber Reinforced ConcreteConstruction and Building Materials23123468347410.1016/j.conbuildmat.2009.08.017Search in Google Scholar
Shaikh F.U.A., Hosan A. (2016). Mechanical properties of steel fibre reinforced geopolymer concretes at elevated temperatures. Construction and Building Materials 114, 15–28.ShaikhF.U.A.HosanA.2016Mechanical properties of steel fibre reinforced geopolymer concretes at elevated temperaturesConstruction and Building Materials114152810.1016/j.conbuildmat.2016.03.158Search in Google Scholar
Jin L., Zhang R., Li L., Yao. Y. (2019). Impact behavior of SFRC beams at elevated temperatures: Experimental and analytical studies. Engineering Structures 197, 109401.JinL.ZhangR.LiL.Yao.Y.2019Impact behavior of SFRC beams at elevated temperatures: Experimental and analytical studiesEngineering Structures19710940110.1016/j.engstruct.2019.109401Search in Google Scholar
Ramazenianpour A.A. Khazali M.H, Vosoughi P. (2013). Effect of steam curing cycle on the strength and durability of SCC: A case study in precast concrete. Construction and Building Materials 49, 807–813.RamazenianpourA.A.KhazaliM.HVosoughiP.2013Effect of steam curing cycle on the strength and durability of SCC: A case study in precast concreteConstruction and Building Materials4980781310.1016/j.conbuildmat.2013.08.040Search in Google Scholar
Ramazenianpour A.M, Esmaeili K. Ghahari S.A, Ramazenianpour AA. (2014). Influence of initial steam curing and different types mineral additives on mechanical and durability properties of self-compacting concrete. Construction and Building Materials 73, 187–194.RamazenianpourA.MEsmaeiliK.GhahariS.ARamazenianpourAA.2014Influence of initial steam curing and different types mineral additives on mechanical and durability properties of self-compacting concreteConstruction and Building Materials7318719410.1016/j.conbuildmat.2014.09.072Search in Google Scholar
Prem P. R., Bharatkumar B.H., Murthy A. R. (2015). Influence of curing regime and steel fibres on the mechanical properties of UHPC. Magazine of Concrete Research, 67, 18.PremP. R.BharatkumarB.H.MurthyA. R.2015Influence of curing regime and steel fibres on the mechanical properties of UHPCMagazine of Concrete Research671810.1680/macr.14.00333Search in Google Scholar
Y. Kong, P. Wang, S. Liu, Z. Gao, (2016). “Hydration and microstructure of cement-based materials under microwave curing”, Construction and Building Materials, 114, 831–838.KongY.WangP.LiuS.GaoZ.2016“Hydration and microstructure of cement-based materials under microwave curing”Construction and Building Materials11483183810.1016/j.conbuildmat.2016.03.202Search in Google Scholar
Aqel M. Panesar D.K. (2016). Hydration kinetics and compressive strength of steam-cured cement pastes and mortars containing limestone filler. Construction and Building Materials 113, 359–368.AqelM.PanesarD.K.2016Hydration kinetics and compressive strength of steam-cured cement pastes and mortars containing limestone fillerConstruction and Building Materials11335936810.1016/j.conbuildmat.2016.03.031Search in Google Scholar
Cecini D. Austin S.A., Cavalaro S., Palmeri A. (2018). Accelerated electric curing of steel-fibre reinforced concrete. Construction and Building Materials 189, 192–204.CeciniD.AustinS.A.CavalaroS.PalmeriA.2018Accelerated electric curing of steel-fibre reinforced concreteConstruction and Building Materials18919220410.1016/j.conbuildmat.2018.08.183Search in Google Scholar
Alimrani N.S., Balazs G.L. (2020). Investigations of direct shear of one-year old SFRC after being exposed to elevated temperatures. Construction and Building Materials, 254, 119–308.AlimraniN.S.BalazsG.L.2020Investigations of direct shear of one-year old SFRC after being exposed to elevated temperaturesConstruction and Building Materials25411930810.1016/j.conbuildmat.2020.119308Search in Google Scholar
Goguen C. (2014). Portland-Limestone Cement. National Precast Concrete Association. Precast Magazines 2.GoguenC.2014Portland-Limestone CementNational Precast Concrete AssociationPrecast Magazines2Search in Google Scholar
TS EN 197-1:2012-Cement-Part 1: Compositions and conformity criteria for common cements.TS EN 197-1:2012-Cement-Part 1: Compositions and conformity criteria for common cementsSearch in Google Scholar
TS EN 934-2:2002-Admixtures for concrete, mortar and grout-Part 2: Concrete admixtures; Definitions, requirements, conformity, marking and labeling.TS EN 934-2:2002-Admixtures for concrete, mortar and grout-Part 2: Concrete admixtures; Definitions, requirements, conformity, marking and labelingSearch in Google Scholar
Standart: TSE-TS-10513-1992-Steel fibres for concrete reinforcement.Standart: TSE-TS-10513-1992-Steel fibres for concrete reinforcementSearch in Google Scholar
TS 10515-1992, Beton-Çelik Tel Takviyeli–Eğilme Mukavemeti Deney Metodu (in Turkish), Türk Standartları Enstitüsü; Ankara (Test methods for flexural strength of steel fiber reinforced concrete, Turkish Standardization Institute, Ankara, Turkey).TS 10515-1992Beton-Çelik Tel Takviyeli–Eğilme Mukavemeti Deney Metodu (in Turkish)Türk Standartları EnstitüsüAnkara(Test methods for flexural strength of steel fiber reinforced concrete, Turkish Standardization Institute, Ankara, Turkey)Search in Google Scholar
TS EN 206-1:2002 Concrete- Part 1: Specification, performance, production and conformity.TS EN 206-1:2002 Concrete- Part 1: Specification, performance, production and conformitySearch in Google Scholar
TS EN 12390-1:2002 Testing hardened concrete-Part 1: Shape, dimensions and other requirements for specimens and molds.TS EN 12390-1:2002 Testing hardened concrete-Part 1: Shape, dimensions and other requirements for specimens and moldsSearch in Google Scholar
Australian Standard, Specification: Part CC35:2007 Low-Pressure Steam Curing.Australian Standard, Specification: Part CC35:2007 Low-Pressure Steam CuringSearch in Google Scholar
Babu R., Santhanam M. (2006). Early age properties of high early strength concrete subjected to steam curing. 31st conference on our world in concrete & structures, Singapore.BabuR.SanthanamM.2006Early age properties of high early strength concrete subjected to steam curing31st conference on our world in concrete & structuresSingaporeSearch in Google Scholar
Talakokula V., Singh R., Vysakh K. (2015). Effect of Delay Time and Duration of Steam Curing on Compressive Strength and Microstructure of Geopolymer Concrete. Advances in Structural Engineering Materials, 978-81-322-2186-9.TalakokulaV.SinghR.VysakhK.2015Effect of Delay Time and Duration of Steam Curing on Compressive Strength and Microstructure of Geopolymer ConcreteAdvances in Structural Engineering Materials978-81-322-2186-910.1007/978-81-322-2187-6_124Search in Google Scholar
TS EN 12350-2-2010 Testing fresh concrete- Part 2: Slump test.TS EN 12350-2-2010 Testing fresh concrete- Part 2: Slump testSearch in Google Scholar
Krasnyy I.M. (1984). Apparatus for determining the viscosity of the concrete mix, Concrete and reinforced concrete, 10-13-14.KrasnyyI.M.1984Apparatus for determining the viscosity of the concrete mix, Concrete and reinforced concrete, 10-13-14Search in Google Scholar
Pikus G.A. (2016). Steel Fiber Concrete Mixture Workability International Conference on Industrial Engineering, ICIE.PikusG.A.2016Steel Fiber Concrete Mixture Workability International Conference on Industrial Engineering, ICIE10.1016/j.proeng.2016.07.250Search in Google Scholar
Sahmaran M., Yaman I.O. (2005a). Hybrid fiber reinforced self-compacting concrete with a high-volume coarse fly ash. Construction and Building Materials 21, 150–156.SahmaranM.YamanI.O.2005aHybrid fiber reinforced self-compacting concrete with a high-volume coarse fly ashConstruction and Building Materials2115015610.1016/j.conbuildmat.2005.06.032Search in Google Scholar
Sahmaran M., Yurtseven A., Yaman I.O. (2005b). Workability of hybrid fiber reinforced self-compacting concrete. Building and Environment, 40; 1672–1677.SahmaranM.YurtsevenA.YamanI.O.2005bWorkability of hybrid fiber reinforced self-compacting concreteBuilding and Environment401672167710.1016/j.buildenv.2004.12.014Search in Google Scholar
Öztürk O., Dalgıç B., Keskin U.S. (2017). Mechanical and workability evalution of self-compacting concrete incorporating high volume ground granulated blast furnace slag, CWB-2-145-153.ÖztürkO.DalgıçB.KeskinU.S.2017Mechanical and workability evalution of self-compacting concrete incorporating high volume ground granulated blast furnace slag, CWB-2-145-153Search in Google Scholar
Yıldırım H. (2006). The effect of steel fiber usage on the workability of self-compacting concrete. Master thesis, Istanbul Technical University.YıldırımH.2006The effect of steel fiber usage on the workability of self-compacting concreteMaster thesisIstanbul Technical UniversitySearch in Google Scholar
Bayasi M.Z., Soroushian P. (1992). Effect of steel fiber reinforcement on fresh mix properties of concrete. ACI Materials Journal 89(4), 369–74.BayasiM.Z.SoroushianP.1992Effect of steel fiber reinforcement on fresh mix properties of concreteACI Materials Journal89436974Search in Google Scholar
Rossi P. (1992). Mechanical behavior of metal-fibre reinforced concretes. Cement Concrete Research 14(1), 3–16.RossiP.1992Mechanical behavior of metal-fibre reinforced concretesCement Concrete Research14131610.1016/0958-9465(92)90034-SSearch in Google Scholar
Dhonde H.B., Mo Y.L., Hsu T.T.C., Vogel J. (2004). Fresh and hardened properties of self-consolidating fiber-reinforced concrete. ACI Materials Journal 04–M54, 491–500.DhondeH.B.MoY.L.HsuT.T.C.VogelJ.2004Fresh and hardened properties of self-consolidating fiber-reinforced concreteACI Materials Journal04–M54491500Search in Google Scholar
Grünewald S. (2004). Performance-based design of self-compacting fiber reinforced concrete. PhD-thesis, the section of structural and building engineering. Delf University of Technology, Netherlands.GrünewaldS.2004Performance-based design of self-compacting fiber reinforced concretePhD-thesis, the section of structural and building engineeringDelf University of TechnologyNetherlandsSearch in Google Scholar
Martinie L., Rossi P., Roussel N. (2010). Rheology of fiber reinforced cementitious materials: classification and prediction. Cement Concrete Research, 40, 226–34.MartinieL.RossiP.RousselN.2010Rheology of fiber reinforced cementitious materials: classification and predictionCement Concrete Research402263410.1016/j.cemconres.2009.08.032Search in Google Scholar
TSE EN Steam Curing of Precast Concrete Products Under Atmospheric Pressure, Ankara/Turkey.TSE EN Steam Curing of Precast Concrete Products Under Atmospheric Pressure, Ankara/TurkeySearch in Google Scholar
Oluokun F.A, Burdette E.G. Deatherage J.H. (1990). Transp. Res. Rec. No. 1284, National Research Council, Washington D.C. 31.OluokunF.ABurdetteE.G.DeatherageJ.H.1990Transp. Res. Rec. No. 1284National Research CouncilWashington D.C.31Search in Google Scholar
Detwiler R.J., Fapohunda C.A., Natale J. (1994). Use of supplementary cementing materials to increase the resistance to chloride ion penetration of concretes cured at elevated temperatures. ACI Materials J. 91; 63–66.DetwilerR.J.FapohundaC.A.NataleJ.1994Use of supplementary cementing materials to increase the resistance to chloride ion penetration of concretes cured at elevated temperaturesACI Materials J.916366Search in Google Scholar
Topçu I.B., Toprak M.U. (2005). Fine aggregate and curing temperature effect on concrete maturity. Cement Concrete Research, 35, 758–762.TopçuI.B.ToprakM.U.2005Fine aggregate and curing temperature effect on concrete maturityCement Concrete Research3575876210.1016/j.cemconres.2004.04.023Search in Google Scholar
Hwang S., Khatib R., Lee H., Lee S., Khayat K. (2012). Optimization of the steam-curing regime for high-strength, self-consolidating concrete for precast, prestressed concrete applications. PCI Journal, 48–62.HwangS.KhatibR.LeeH.LeeS.KhayatK.2012Optimization of the steam-curing regime for high-strength, self-consolidating concrete for precast, prestressed concrete applicationsPCI Journal486210.15554/pcij.06012012.48.62Search in Google Scholar
Zheng Y., Wu X., He G., Shang Q., Xu J., Sun J. (2018). Mechanical properties of steel fiber-reinforced concrete by vibratory mixing Technology. Advances in Civil Engineering, 9025715.ZhengY.WuX.HeG.ShangQ.XuJ.SunJ.2018Mechanical properties of steel fiber-reinforced concrete by vibratory mixing TechnologyAdvances in Civil Engineering902571510.1155/2018/9025715Search in Google Scholar
Larsen I.L., Thorstensen R.T. (2020). The influence of steel fibres on compressive and tensile strength of ultra high performance concrete: A review. Construction and Building Materials 256, 119459.LarsenI.L.ThorstensenR.T.2020The influence of steel fibres on compressive and tensile strength of ultra high performance concrete: A reviewConstruction and Building Materials25611945910.1016/j.conbuildmat.2020.119459Search in Google Scholar
Mahadık S. A., Kamane S. K., Lande A. C. (2014). Effect of Steel Fibers on Compressive and Flexural Strength of Concrete. International Journal of Advanced Structures and Geotechnical Engineering 03, 04.MahadıkS. A.KamaneS. K.LandeA. C.2014Effect of Steel Fibers on Compressive and Flexural Strength of ConcreteInternational Journal of Advanced Structures and Geotechnical Engineering0304Search in Google Scholar
Khaloo A.R. Sharifian M. (2005). Experimental ınvestigation of low to hıgh strength steel fıber reınforced lightweight concrete under pure torsion. Asian Journal of Civil Engineering 6, 533–547.KhalooA.R.SharifianM.2005Experimental ınvestigation of low to hıgh strength steel fıber reınforced lightweight concrete under pure torsionAsian Journal of Civil Engineering6533547Search in Google Scholar
Song P.S. Hwang S. (2004). Mechanical properties of high-strength steel fiber-reinforced concrete. Construction and Building Materials 18, 669–673.SongP.S.HwangS.2004Mechanical properties of high-strength steel fiber-reinforced concreteConstruction and Building Materials1866967310.1016/j.conbuildmat.2004.04.027Search in Google Scholar
Ünal O, Uygunoğlu T. (2005) Farklı Ortamlarda Kür Edilmiş Lif Katkılı Betonların Deprem Yükü Etkisi Altındaki Davranışının Araştırılması, Deprem Sempozyumu (Investigation of the behavior of fiber reinforced concrete cured in different rnvironments under earthquake load) (in Turkish), Kocaeli.ÜnalOUygunoğluT.2005Farklı Ortamlarda Kür Edilmiş Lif Katkılı Betonların Deprem Yükü Etkisi Altındaki Davranışının Araştırılması, Deprem Sempozyumu(Investigation of the behavior of fiber reinforced concrete cured in different rnvironments under earthquake load) (in Turkish)KocaeliSearch in Google Scholar
Ba M., Qian C., Guo X., Han X. (2011). Effects of steam curing on strength and porous structure of concrete with low water/binder ratio. Construction and Building Materials 25, 123–128.BaM.QianC.GuoX.HanX.2011Effects of steam curing on strength and porous structure of concrete with low water/binder ratioConstruction and Building Materials2512312810.1016/j.conbuildmat.2010.06.049Search in Google Scholar
Gonzalez-Corominas A., Etxeberria M. (2014). Experimental analysis of properties of high performance recycled aggregate concrete. Construction and Building Materials 52; 227–235.Gonzalez-CorominasA.EtxeberriaM.2014Experimental analysis of properties of high performance recycled aggregate concreteConstruction and Building Materials5222723510.1016/j.conbuildmat.2013.11.054Search in Google Scholar
Kou S.C., Poon C.S., Chan D. (2007). Influence of fly ash as a cement addition on the hardened properties of recycled aggregate concrete. Materials Structures 41, 1191–1201.KouS.C.PoonC.S.ChanD.2007Influence of fly ash as a cement addition on the hardened properties of recycled aggregate concreteMaterials Structures411191120110.1617/s11527-007-9317-ySearch in Google Scholar
Kou S.C., Poon C.S., Agrela F. (2011). Comparisons of natural and recycled aggregate concretes prepared with the addition of different mineral admixtures. Cement Concrete Research 33; 788–795.KouS.C.PoonC.S.AgrelaF.2011Comparisons of natural and recycled aggregate concretes prepared with the addition of different mineral admixturesCement Concrete Research3378879510.1016/j.cemconcomp.2011.05.009Search in Google Scholar
Kou S., Poon C., Chan D. (2004). Properties of steam-cured recycled aggregate fly ash concrete in E. Vázquez, C. Hendriks, G. 541 Janssen (Eds.), Int. RILEM Conf. Use Recycle. Mater. Build. Struct., RILEM Publications SARL, Barcelona, Spain, 542-590-9.KouS.PoonC.ChanD.2004Properties of steam-cured recycled aggregate fly ash concrete in EVázquezC.HendriksG.541 Janssen (Eds.)Int. RILEM Conf. Use Recycle. Mater. Build. Struct.RILEM Publications SARLBarcelona, Spain5425909Search in Google Scholar
Lie, T. T., Kodur, V.K.R. (1996). Expansion of steel fiber in steel fiber reinforced concrete (Effect of temperature on thermal and mechanical properties of steel fibre reinforced concrete Canadian Journal of Civil Engineering 23, 2.LieT. T.KodurV.K.R.1996Expansion of steel fiber in steel fiber reinforced concrete (Effect of temperature on thermal and mechanical properties of steel fibre reinforced concreteCanadian Journal of Civil Engineering23210.1139/l96-055Search in Google Scholar
Lau, A., Anson, M. (2006). Effect of high temperatures on the high performance steel fibre reinforced concrete. Cement and Concrete Research, 36, 1698–1707.LauA.AnsonM.2006Effect of high temperatures on the high performance steel fibre reinforced concreteCement and Concrete Research361698170710.1016/j.cemconres.2006.03.024Search in Google Scholar