International Journal of Concrete Technology

This review paper discusses about the different types of fibre used in concrete at different periods with the mix parameter details. This review enlightens the effect of industrial waste such as Bottom ash, Copper slag, Ferro-chromium slag, Ground granulated blast furnace slag (GGBFS), Steel slag, Stainless steel slag as a substitute in concrete. The elaborate study on its chemical composition and also the merits and demerits of using the slag are discussed. The experimental work carried out with mix proportion, w/c ratio of these industrial wastes in concrete is elaborately tabulated. The detail study reveals that more research work is required for the long term durability studies on the Copper slag, Ferro chromium slag, Steel slag and Stainless steel slag.

Sai Prasad P.V, Jha K. High Performance Concrete.

Gencel O., Ozel C., Browstow W., et al. Mechanical properties of self-compacting concrete reinforced with polypropylene fibres. Materials Research Innovations. 2011; 15(3): 216–25p.

Daneil I.J., Balaguru P.N., Guerra A.J., et al. State-of-the-Art Report on Fibre Reinforced Concrete. Reported by ACI Committee 544. 2002.

Al-Jabri K.S., Al-Saidy A.H., Taha R. Effect of copper slag as a fine aggregate on the properties of cement mortars and concrete. Construction and Building Materials. 2011; 25(2): 933–8p.

Brito J.D., Saikia N. Recycled Aggregate in Concrete: Use of industrial construction and demolition wastes. Green Energy and Technology. London: Springer-Verlag; 2013.

doi:10.1007/978-1-4471-4540-0_2

Aydın S., Baradan B. The effect of fibre properties on high performance alkali-activated slag/silica fume mortars. Composites: Part B Engineering. 2013; 45(1): 63–9p.

Ramadoss P. Modelling for the evaluation of strength and toughness of high performance fiber reinforced concrete. Journal of Engineering Science and Technology. 2012; 7( 3): 280–91p.

Poon C.S., Shui Z.H., Lam L. Compressive behaviour of fibre reinforced high performance concrete subjected to elevated temperatures. Cement and Concrete Research. 2004; 34: 2215–22p.

doi:10.1016/j.cemconres.2004.02.011

Abou-zeid M.N., Fahmy E.H., Massoud M.T. Interaction of silica fume and polypropylene fibres in high performance concrete. Proceedings of 2nd Material Specialty Conference of the Canadian Society for Civil Engineering. 2002 Jun 5–8; Montreal, Quebec, Canada.

Nataraja M.C., Nagaraj T.S., Basavaraja S.B. Re-proportioning of steel fibre reinforced concrete mixes and their impact resistance. Cement and Concrete Research. 2005; 35(12): 2350–9p.

doi:10.1016/j.cemconres.2005.06.011

Harun Tanyildizi. Effect of temperature, carbon fibres, and silica fume on the mechanical properties of light weight concretes. New Carbon Materials. 2008; 23(4): 339–44p.

Ramadoss P., Nagamani K. Tensile strength and durability Characteristics of high-performance Fibre Reinforced concrete. The Arabian journal for Science and Engineering. 2008; 33(2b): 307–19p.

Tanyildizi H. Statistical analysis for mechanical properties of polypropylene fibre reinforce Light weight concrete containing silica fume exposed to high temperature. Materials and Design. 2009; 30(8): 3252–8p.

Ghorpade V.G. An experimental investigation on glass fibre reinforced high performance concrete with silica fume as admixture. Proceedings of 35th conference on our world in concrete& structures. 2010 Aug 25–27; Singapore. CI-PREMIER PTE Ltd. Singapore.

Soutsos M.N., Le T.T., Lampropoulos A.P. Flexural performance of fibre reinforced concrete made with steel and synthetic fibres. Construction and Building Materials. 2012; 36: 704–10p.

doi:10.1016/j.conbuildmat.2012.06.042

Ramadoss P. Modelling for the evaluation of strength and toughness of high- performance fibre reinforced concrete. Journal of Engineering Science and Technology. 2012; 7(3): 280–91p.

Gesoglu M., Guneyisi E., Alzeebaree R., et al. Effect of silica fume and steel fibre on the mechanical properties of the Concrete produced with cold bonded fly ash aggregates. Construction and Building Materials. 2013; 40: 982–90p.

Guneyisi E., Gesoglu M., İpek S.V. Effect of steel fibre addition and aspect ratio on bond strength of cold-bonded fly ash lightweight aggregate concrete. Construction and Building Materials. 2013; 47: 358–65p.

Yap S.P., Alengaram U.J., Jumaat Z. Enhancement of mechanical properties in polypropylene and nylon fibre reinforced oil palm shell concrete. Materials and Design. 2013; 49: 1034–41p.

doi:10.1016/j.matdes.2013.02.070

Ali M., Liu A., Sou H., et al. Mechanical and dynamic properties of coconut fibre reinforced concrete. Construction and Building Materials. 2012; 30: 814–25p.

Cavdar A. The effects of high temperature on mechanical properties of cementitious composites reinforced with polymeric fibres. Composites: Part B Engineering. 2013; 45(1): 78–88p.

Gao D., Yan D., Li X. Splitting strength of GGBFS concrete incorporating with steel fibre and polypropylene fibre after exposure to elevated temperatures. Fire Safety Journal. 2012; 54: 67–73p.

doi:10.1016/j.firesaf.2012.07.009

Niu D., Jiang L., Bai M., et al. Study of the performance of steel fibre reinforced concrete to water and salt freezing condition. Materials and Design. 2013; 44: 267–73p.

doi:10.1016/j.matdes.2012.07.074

Zhang P., Li O. Effect of polypropylene fibre on durability of concrete composite containing fly ash and silica fume. Composites: Part B Engineering. 2013; 45: 1587–94p.

doi:10.1016/j.compositesb.2012.10.006

Ganesan N., Indira P.V., Sabeena. M.V. Bond stress slip response of bars embedded in hybrid fibre high performance concrete. Construction and Building Materials. 2014; 50: 108–15p.

Yi H., Xu G., Cheng H., et al. An overview of utilization of steel slag. The 7th International Conference on Waste Management and Technology; 2012; Procedia Environmental Sciences. Elsevier; 2012; 16: 791–801p.

Bai Y., Darcy F., Basheer P.A.M. Strength and drying shrinkage properties of concrete containing furnace bottom ash as fine aggregate. Construction and Building Materials. 2005; 19: 691–7p.

Aggarwal P., Aggarwal Y., Gupta S.M. Effect of bottom ash as replacement of fine aggregates in concrete. Asian journal of civil engineering (building and housing). 2007; 8(1); 49–62p.

Kou S.C., Poon C.S. Properties of concrete prepared with crushed fine stone, furnace bottom ash and fine recycled aggregate as fine aggregates. Construction and Building Materials. 2009; 23(8): 2877–86p.

Kim H.K., Lee H.K. Use of power plant bottom ash as fine and coarse aggregates in high-strength concrete. Construction and Building Materials. 2011; 25(2): 1115–22p.

Wongkeo W., Thongsanitgarn P., Pimraksa K., et al. Compressive strength, flexural strength and thermal conductivity of autoclaved concrete block made using bottom ash as cement replacement materials. Materials and Design. 2012; 35: 434–9p.

doi:10.1016/j.matdes.2011.08.046

Kim H.K., Jeon J.H., Lee H.K. Flow, water absorption, and mechanical characteristics of normal and high-strength mortar incorporating fine bottom ash aggregates. Construction and Building Material. 2012; 26: 249–56p.

Bajare D., Bumanis G., Upeniece L. Coal Combustion Bottom Ash as Micro filler with Pozzolanic Properties for Traditional Concrete. 2013; Procedia Engineering. 2013; 57: 149–58p.

Al-Jabri K.S., Taha R.A., Al-Hashmy A., et al. Effect of copper slag and cement by-pass dust addition on mechanical properties of concrete. Construction and Building Materials. 2006; 20(5): 322–31p.

Moura W.A., Goncalves J.P., LeiteLima M.B. Copper slag waste as a supplementary cementing material to concrete. Journal of Material Sciences. 2007; 42(7): 2226–30p.

doi:10.1007/s10853-006-0997-4

Khanzadi M., Behnood A. Mechanical properties of high-strength concrete incorporating copper slag as coarse aggregate. Construction and Building Materials. 2009; 23(6): 2183–8p.

Wu W., Zhang W., Ma G. Optimum content of copper slag as a fine aggregate in high strength concrete. Materials and Design. 2010; 31: 2878–83p.

doi:10.1016/j.matdes.2009.12.037

Wu W., Zhang W., Ma G. Mechanical properties of copper slag reinforced concrete under dynamic compression. Construction and Building Materials. 2010; 24(6): 910–7p.

Brindha D., Nagan S. Durability studies on copper slag admixed concrete. Asian journal of civil engineering (building and housing). 2011; 12(5): 563–78p.

Najimi M., Sobhani J., Pourkhorshidi A.R. Durability of copper slag contained concrete exposed to sulfate attack. Construction and Building Materials. 2011; 25: 1895–1905p.

Zelic J. Properties of concrete pavements prepared with ferrochromium slag as concrete aggregate. Cement and Concrete Research. 2005; 35(12): 2340–9p.

doi:10.1016/j.cemconres.2004.11.019

Yilmaz M., Vuralkok B. Effect of ferrochromium slag with neat and polymer modified binders in hot Bituminous mix. Indian journal of Engineering and Material Sciences. 2009; 16: 310–8p.

Gencel O., Koksal F., Ozel C., et al. Combined effects of fly ash and waste ferrochromium on properties of concrete. Construction and Building Materials. 2012; 29: 633–40p.

Panda C.R., Mishra K.K., Panda K.C., et al. Environmental and technical assessment of ferrochrome slag as concrete aggregate material. Construction and Building Materials. 2013; 49: 262–71p.

Yeau K.Y., Kim E.K. An experimental study on corrosion resistance of concrete with ground granulate blast-furnace slag. Cement and Concrete Research. 2005; 35(7): 1391–9p.

doi:10.1016/j.cemconres.2004.11.010

Wang H.Y. The effects of elevated temperature on cement paste containing GGBFS. Cement & Concrete Composites. 2008; 30(10): 992–9p.

Cakır O., Akoz F. Effect of curing conditions on the mortars with and without GGBFS. Construction and Building Materials. 2008; 22(3): 308–14p.

Chidiac S.E., Panesar D.K. Evolution of mechanical properties of concrete containing ground granulated blast furnace slag and effects on the scaling resistance test at 28 days. Cement & Concrete Composites. 2008; 30(2): 63–71p.

Guneyisi E., Gesoglu M. A study on durability properties of high- performance concretes incorporating high replacement levels of slag. Materials and Structures. 2008; 41(3): 479–93p.

doi:10.1617/s11527-007-9260-y

Garcia J.I.E., Espinoza-Perez L.J., Gorokhovsky A. Coarse blast furnace slag as a cementitious material: comparative study as a partial replacement of Portland cement and as an alkali activated cement. Construction and Building Materials. 2009; 23(7): 2511–7p.

Gesoglu M., Guneyis E., Oznur H.O. Properties of lightweight aggregates produced with cold-bonding palletisation of fly ash and ground granulated blast furnace slag. Materials and Structures. 2012; 45(10): 1535–46p.

doi:10.1617/s11527-012-9855-9

Shariq M., Prasad J., Masood A. Studies in ultrasonic pulse velocity of concrete containing GGBFS. Construction and Building Materials. 2013; 40, 944–50p.

Manso J.M., Polanco J.A., Losanez M., et al. Durability of concrete made with EAF slag as aggregate. Cement &Concrete Composites. 2006; 28: 528–34p.

Guo X., Shi H. Modification of steel slag powder by mineral admixture and chemical activators to utilize in cement-based materials. Materials and Structures. 2013; 46: 1265–73p.

doi:10.1617/s11527-012-9970-7.

Wang Q., Yan P., Yang J., et al. Influence of steel slag on mechanical properties and durability of concrete. Construction and Building Materials. 2013; 47: 1414–20p.

Viana C.E., Dias D.P, Holanda J.N.F., et al. The Use of Submerged-Arc Welding Flux Slag as Raw Material for the Fabrication of Multiple-Use Mortars and Bricks. Soldagem & Inspecao, Brasil. 2009; 14(3).

Ramesh S.T., Gandhimathi R., Nidheesh P.V., et al. Use of furnace slag and welding slag as replacement for sand in concrete. International Journal of Energy and Environmental Engineering. 2013; 4(3).

Kriskova L., Pontikes Y., Cizer O., et al. Effect of mechanical activation on the hydraulic properties of stainless steel slags. Cement and Concrete Research. 2012; 42(6): 778–88p.

doi:10.1016/j.cemconres.2012.02.016

Sheen Y.N., Wang H.Y., Sun T.H. A study of engineering properties of cement mortar with stainless steel oxidizing slag and reducing slag resource materials. Construction and Building Materials. 2013; 40: 239–45p.

Sheen Y.N., Wang H.Y., Sun T.H. Properties of green concrete containing stainless steel oxidizing slag resource materials. Construction and Building Materials. 2014; 50: 22–7p.