| Abstract |
: |
When used in conjunction with cementitious mortar, recycled coarse aggregates (RCA) from demolition and rubble debris have numerous financial and environmental advantages by reducing carbon dioxide (CO2) emissions, minimising wasteful resource consumption, and assisting in a cleaner concrete manufacturing process. This paper evaluates fresh properties, durability properties and compressive strength (CSs) of self-compacting concrete (SCC) using RCA and silica fume (SF). Therefore, in this study, the effects of partial replacements of natural coarse aggregate (NCA) by RCA and ordinary Portland cement (OPC) by SF in the SCC mixes, cured in normal tap-water and also, in the presence of sodium sulphate (Na2SO4) solutions (2.0 g/l) for the exposure period of 28, 180 and 270 days, are investigated. Three different SCC mixes – control mix (CM) [OPC (100%) +NCA (100%)] whereas the other mixes have been designated as Mix-SF10 [OPC (90%) + SF (10%) + NCA (100%)] and Mix-SF10RCA25 [OPC (90%) + SF (10%) + NCA (75%) + RCA (25%)]. The fresh and hardened properties of the mixes, along with their microstructural properties were determined. The change in microstructure of the SCC mixes due to sulphate attack were investigated by X-ray diffraction (XRD). It is concluded that fresh properties are increased up to an optimum level of SF content (SF-10%) and in case of RCA, the trend reverses; the gain in CSs of different SCC in normal tap-water is lies between 6.76-25.00%, and reductions in CSs of SCC mixes exposed to Na2SO4 solution is in the range of 0.75-7.01 % in comparison to the SCC mixes’s strength in normal tap-water. In contrast to the CM, the Na2SO4 attack had a smaller impact on the SCC mix, which contained SF viz., SF10 and SF10RCA25. |
| References |
: |
|
[1]Naqi A, Jang JG. Recent progress in green cement technology utilizing low-carbon emission fuels and raw materials: a review. Sustainability. 2019; 11(2):1-18.
|
| [Crossref] |
[Google Scholar] |
|
[2]Nicoara AI, Stoica AE, Vrabec M, Šmuc RN, Sturm S, Ow-yang C, et al. End-of-life materials used as supplementary cementitious materials in the concrete industry. Materials. 2020; 13(8):1-20.
|
| [Crossref] |
[Google Scholar] |
|
[3]Dinakar P, Sahoo PK, Sriram G. Effect of metakaolin content on the properties of high strength concrete. International Journal of Concrete Structures and Materials. 2013; 7(3):215-23.
|
| [Crossref] |
[Google Scholar] |
|
[4]Salesa Á, Esteban LM, Lopez-julian PL, Pérez-benedicto JÁ, Acero-oliete A, Pons-ruiz A. Evaluation of characteristics and building applications of multi-recycled concrete aggregates from precast concrete rejects. Materials. 2022; 15(16):1-19.
|
| [Crossref] |
[Google Scholar] |
|
[5]Zhang LW, Sojobi AO, Kodur VK, Liew KM. Effective utilization and recycling of mixed recycled aggregates for a greener environment. Journal of Cleaner Production. 2019.
|
| [Crossref] |
[Google Scholar] |
|
[6]Nandhini K, Ponmalar V. Effect of blending micro and nano silica on the mechanical and durability properties of self-compacting concrete. Silicon. 2021; 13(3):687-95.
|
| [Crossref] |
[Google Scholar] |
|
[7]Singh N, Kumar P, Goyal P. Reviewing the behaviour of high volume fly ash based self compacting concrete. Journal of Building Engineering. 2019.
|
| [Crossref] |
[Google Scholar] |
|
[8]Nagajothi S, Elavenil S. Effect of GGBS addition on reactivity and microstructure properties of ambient cured fly ash based geopolymer concrete. Silicon. 2021; 13(2):507-16.
|
| [Crossref] |
[Google Scholar] |
|
[9]Wu Y, Liu C, Liu H, Hu H, He C, Song L, et al. Pore structure and durability of green concrete containing recycled powder and recycled coarse aggregate. Journal of Building Engineering. 2022.
|
| [Crossref] |
[Google Scholar] |
|
[10]Sasanipour H, Aslani F. Durability properties evaluation of self-compacting concrete prepared with waste fine and coarse recycled concrete aggregates. Construction and Building Materials. 2020.
|
| [Crossref] |
[Google Scholar] |
|
[11]Kotwal S, Singh H, Kumar R. Experimental investigation of steel fibre reinforced self compacting concrete (SCC) using recycled aggregates as partial replacement of coarse aggregates. Materials Today: Proceedings. 2022; 48:1032-7.
|
| [Crossref] |
[Google Scholar] |
|
[12]Kotwal S, Singh H, Kumar R. Study on sulphate and chloride resistance of self-compacting concrete. Materials Today: Proceedings. 2022; 48:1044-7.
|
| [Crossref] |
[Google Scholar] |
|
[13]Singh SK. Impact of using recycled demolition waste as aggregates in steel fiber reinforced self-compacting concrete on its durability properties. Materials Today: Proceedings. 2022; 48:1666-72.
|
| [Crossref] |
[Google Scholar] |
|
[14]Zheng Y, Zhang Y, Zhang P. Methods for improving the durability of recycled aggregate concrete: a review. Journal of Materials Research and Technology. 2021; 15:6367-86.
|
| [Crossref] |
[Google Scholar] |
|
[15]Benabed B, Kadri EH, Azzouz L, Kenai S. Properties of self-compacting mortar made with various types of sand. Cement and Concrete Composites. 2012; 34(10):1167-73.
|
| [Crossref] |
[Google Scholar] |
|
[16]Sua-iam G, Makul N. Utilization of high volumes of unprocessed lignite-coal fly ash and rice husk ash in self-consolidating concrete. Journal of Cleaner Production. 2014; 78:184-94.
|
| [Crossref] |
[Google Scholar] |
|
[17]Evangelista LM, De BJM. Concrete with fine recycled aggregates: a review. European Journal of Environmental and Civil Engineering. 2014; 18(2):129-72.
|
| [Crossref] |
[Google Scholar] |
|
[18]Kumar BV, Ananthan H, Balaji KV. Experimental studies on utilization of coarse and finer fractions of recycled concrete aggregates in self compacting concrete mixes. Journal of Building Engineering. 2017; 9:100-8.
|
| [Crossref] |
[Google Scholar] |
|
[19]Kenai S, Menadi B, Debbih A, Kadri EH. Effect of recycled concrete aggregates and natural pozzolana on rheology of self-compacting concrete. In key engineering materials 2014 (pp. 256-63). Trans Tech Publications Ltd.
|
| [Crossref] |
[Google Scholar] |
|
[20]Boudali S, Kerdal DE, Ayed K, Abdulsalam B, Soliman AM. Performance of self-compacting concrete incorporating recycled concrete fines and aggregate exposed to sulphate attack. Construction and Building Materials. 2016; 124:705-13.
|
| [Crossref] |
[Google Scholar] |
|
[21]Sadek DM, El-attar MM, Ali HA. Reusing of marble and granite powders in self-compacting concrete for sustainable development. Journal of Cleaner Production. 2016; 121:19-32.
|
| [Crossref] |
[Google Scholar] |
|
[22]IS I. 8112-1989 “Specification 43 grade ordinary Portland cement”. Bureau of Indian Standards, New Delhi, India. 1989.
|
| [Google Scholar] |
|
[23]https://law.resource.org/pub/in/bis/S03/is.15388.2003.pdf. Accessed 05 November 2022.
|
|
[24]https://www.iitk.ac.in/ce/test/IS-codes/is.383.1970.pdf. Accessed 05 November 2022.
|
|
[25]EFNARC S. Guidelines for self-compacting concrete. London, UK: Association House. 2002.
|
| [Google Scholar] |
|
[26]https://www.iitk.ac.in/ce/test/IS-codes/is.516.1959.pdf. Accessed 05 November 2022.
|
|
[27]Nel QP, Fowler DW. The effects of aggregate characteristics on the performance of portland cement concrete (Doctoral Dissertation, The University of Texas). International Center for Aggregates Research, Austin, USA. 2003.
|
| [Google Scholar] |
|
[28]Bravo M, De BJ, Pontes J, Evangelista L. Mechanical performance of concrete made with aggregates from construction and demolition waste recycling plants. Journal of Cleaner Production. 2015; 99:59-74.
|
| [Crossref] |
[Google Scholar] |
|
[29]Holland TC. Silica fume user s manual. Federal Highway Administration; 2005.
|
| [Google Scholar] |
|
[30]Omrane M, Kenai S, Kadri EH, Aït-mokhtar A. Performance and durability of self compacting concrete using recycled concrete aggregates and natural pozzolan. Journal of Cleaner Production. 2017; 165:415-30.
|
| [Crossref] |
[Google Scholar] |
|
[31]Kapoor K, Singh SP, Singh B. Durability of self-compacting concrete made with recycled concrete aggregates and mineral admixtures. Construction and Building Materials. 2016; 128:67-76.
|
| [Crossref] |
[Google Scholar] |
|
[32]Carro-lópez D, González-fonteboa B, Martínez-abella F, González-taboada I, De BJ, Varela-puga F. Proportioning, microstructure and fresh properties of self-compacting concrete with recycled sand. Procedia Engineering. 2017; 171:645-57.
|
| [Crossref] |
[Google Scholar] |
|
[33]Dhiyaneshwaran S, Ramanathan P, Baskar I, Venkatasubramani R. Study on durability characteristics of self-compacting concrete with fly ash. Jordan Journal of Civil Engineering. 2013; 7(3):342-53.
|
| [Google Scholar] |
|
[34]Nehdi M, Pardhan M, Koshowski S. Durability of self-consolidating concrete incorporating high-volume replacement composite cements. Cement and Concrete Research. 2004; 34(11):2103-12.
|
| [Crossref] |
[Google Scholar] |
|
[35]Bassuoni MT, Nehdi ML. Resistance of self-consolidating concrete to ammonium sulphate attack. Materials and Structures. 2012; 45(7):977-94.
|
| [Crossref] |
[Google Scholar] |
|
[36]Mohammed MK, Dawson AR, Thom NH. Macro/micro-pore structure characteristics and the chloride penetration of self-compacting concrete incorporating different types of filler and mineral admixture. Construction and Building Materials. 2014; 72:83-93.
|
| [Crossref] |
[Google Scholar] |
|
[37]Li W, Xiao J, Sun Z, Kawashima S, Shah SP. Interfacial transition zones in recycled aggregate concrete with different mixing approaches. Construction and Building Materials. 2012; 35:1045-55.
|
| [Crossref] |
[Google Scholar] |
|
[38]Motohashi K. Evaluation methods of concrete carbonation suppressive performance of surface coating. In third international conference on sustainable construction materials and technologies 2013 (pp. 19-21).
|
| [Google Scholar] |
|
[39]Brito JD, Robles R. Recycled aggregate concrete (RAC) methodology for estimating its long-term properties. Indian Journal of Engineering and Materials Sciences. 2010; 17(6):449-62.
|
| [Google Scholar] |
|
Full-Text PDF
