Recycling of foundry sand wastes in self-compacting concretes: Use as cementitious materials and fine aggregates

[1] Lindsay, B.J., Logan, T.J. (2005): Agricultural reuse of foundry sand. Journal of Residuals Science & Technology, 2(1), p. 3. LindsayB.J. LoganT.J. 2005 Agricultural reuse of foundry sand Journal of Residuals Science & Technology 2 1 3 Search in Google Scholar

[2] Naik, T.R., Singh, S.S. (1997): Flowable slurry containing foundry sands. Journal of Materials in Civil Engineering, 9(2), pp. 93–102. NaikT.R. SinghS.S. 1997 Flowable slurry containing foundry sands Journal of Materials in Civil Engineering 9 2 93 102 Search in Google Scholar

[3] Sen, T., Mishra, U. (2010): Usage of industrial waste products in village road construction. International Journal of Environmental Science and Development, 1(2), pp. 122. SenT. MishraU. 2010 Usage of industrial waste products in village road construction International Journal of Environmental Science and Development 1 2 122 Search in Google Scholar

[4] Alonso-Santurde, R., Andrés, A., Viguri, J.R., Raimondo, M., Guarini, G., Zanelli, C., Dondi, M. (2011): Technological behaviour and recycling potential of spent foundry sands in clay bricks. Journal of Environmental Management, 92(3), pp. 994–1002. Alonso-SanturdeR. AndrésA. ViguriJ.R. RaimondoM. GuariniG. ZanelliC. DondiM. 2011 Technological behaviour and recycling potential of spent foundry sands in clay bricks Journal of Environmental Management 92 3 994 1002 Search in Google Scholar

[5] Carpenter, A.C., Gardner, K.H. (2009): Use of industrial by-products in urban roadway infrastructure: Argument for increased industrial ecology. Journal of Industrial Ecology, 13(6), pp. 965–977. CarpenterA.C. GardnerK.H. 2009 Use of industrial by-products in urban roadway infrastructure: Argument for increased industrial ecology Journal of Industrial Ecology 13 6 965 977 Search in Google Scholar

[6] De Koff, J.P., Lee, B.D., Dungan, R.S. (2008): Amelioration of physical strength in waste foundry green sands for reuse as a soil amendment. Journal of Environmental Quality, 37(6), pp. 2332–2338. De KoffJ.P. LeeB.D. DunganR.S. 2008 Amelioration of physical strength in waste foundry green sands for reuse as a soil amendment Journal of Environmental Quality 37 6 2332 2338 Search in Google Scholar

[7] Lin, K.L., Cheng, C.J., Cheng, A., Chao, S.J. (2012): Study on recycled waste foundry sand as raw materials of cement additives. Sustainable Environment Research, 22(2), pp. 91–97. LinK.L. ChengC.J. ChengA. ChaoS.J. 2012 Study on recycled waste foundry sand as raw materials of cement additives Sustainable Environment Research 22 2 91 97 Search in Google Scholar

[8] Dungan, R.S., Kim, J.S., Weon, H.Y., Leytem, A.B. (2009): The characterization and composition of bacterial communities in soils blended with spent foundry sand. Annals of Microbiology, 59, pp. 239–246. DunganR.S. KimJ.S. WeonH.Y. LeytemA.B. 2009 The characterization and composition of bacterial communities in soils blended with spent foundry sand Annals of Microbiology 59 239 246 Search in Google Scholar

[9] Naik, T.R., Singh, S.S. (1997): Flowable slurry containing foundry sands. Journal of Materials in Civil Engineering, 9(2), pp. 93–102. NaikT.R. SinghS.S. 1997 Flowable slurry containing foundry sands Journal of Materials in Civil Engineering 9 2 93 102 Search in Google Scholar

[10] Javed, S. (1992): Use of Waste Foundry Sand in Highway Construction: Interim Report. JavedS. 1992 Use of Waste Foundry Sand in Highway Construction: Interim Report Search in Google Scholar

[11] Mgangira, M.B., Jones, G.A. (2006): Laboratory assessment of the influence of the proportion of waste foundry sand on the geotechnical engineering properties of clayey soils. Journal of the South African Institution of Civil Engineering, 48(1), pp. 2–7. MgangiraM.B. JonesG.A. 2006 Laboratory assessment of the influence of the proportion of waste foundry sand on the geotechnical engineering properties of clayey soils Journal of the South African Institution of Civil Engineering 48 1 2 7 Search in Google Scholar

[12] Lee, K., Cho, J., Salgado, R., Lee, I. (2001): Retaining wall model test with waste foundry sand mixture backfill. Geotechnical Testing Journal, 24(4), pp. 401–408. LeeK. ChoJ. SalgadoR. LeeI. 2001 Retaining wall model test with waste foundry sand mixture backfill Geotechnical Testing Journal 24 4 401 408 Search in Google Scholar

[13] Naik, T.R., Singh, S.S., Tharaniyil, M.P., Wendorf, R.B. (1996): Application of foundry by-product materials in manufacture of concrete and masonry products. Materials Journal, 93(1), pp. 51–60. NaikT.R. SinghS.S. TharaniyilM.P. WendorfR.B. 1996 Application of foundry by-product materials in manufacture of concrete and masonry products Materials Journal 93 1 51 60 Search in Google Scholar

[14] Khatib, J.M., Baig, S., Bougara, A., Booth, C. (2010, June): Foundry sand utilisation in concrete production. In Second International Conference on Sustainable Construction Materials and Technologies (Vol. 1, pp. 4507–1490). Ancona: Università Politecnica delle Marche Home. KhatibJ.M. BaigS. BougaraA. BoothC. 2010 June Foundry sand utilisation in concrete production In Second International Conference on Sustainable Construction Materials and Technologies 1 4507 1490 Ancona Università Politecnica delle Marche Home Search in Google Scholar

[15] Singh, G., Siddique, R. (2012): Effect of waste foundry sand (WFS) as partial replacement of sand on the strength, ultrasonic pulse velocity and permeability of concrete. Construction and Building Materials, 26(1), pp. 416–422. SinghG. SiddiqueR. 2012 Effect of waste foundry sand (WFS) as partial replacement of sand on the strength, ultrasonic pulse velocity and permeability of concrete Construction and Building Materials 26 1 416 422 Search in Google Scholar

[16] Monosi, S., Sani, D., Tittarelli, F. (2010): Used foundry sand in cement mortars and concrete production. The Open Waste Management Journal, 3(1), pp. 18–25. MonosiS. SaniD. TittarelliF. 2010 Used foundry sand in cement mortars and concrete production The Open Waste Management Journal 3 1 18 25 Search in Google Scholar

[17] Bhardwaj, B., Kumar, P. (2017): Waste foundry sand in concrete: A review. Construction and Building Materials, 156, pp. 661–674. BhardwajB. KumarP. 2017 Waste foundry sand in concrete: A review Construction and Building Materials 156 661 674 Search in Google Scholar

[18] Bradshaw, S.L., Benson, C.H., Olenbush, E.H., Melton, J.S. (2010): Using foundry sand in green infrastructure construction. In: Green Streets and Highways 2010: An Interactive Conference on the State of the Art and How to Achieve Sustainable Outcomes (pp. 280–298). BradshawS.L. BensonC.H. OlenbushE.H. MeltonJ.S. 2010 Using foundry sand in green infrastructure construction In: Green Streets and Highways 2010: An Interactive Conference on the State of the Art and How to Achieve Sustainable Outcomes 280 298 Search in Google Scholar

[19] Mavroulidou, M., Lawrence, D. (2019): Can waste foundry sand fully replace structural concrete sand? Journal of Material Cycles and Waste Management, 21, pp. 594–605. MavroulidouM. LawrenceD. 2019 Can waste foundry sand fully replace structural concrete sand? Journal of Material Cycles and Waste Management 21 594 605 Search in Google Scholar

[20] Siddique, R., Gupta, R., Kaur, I. (2007): Effect of spent foundry sand as partial replacement of fine aggregate on the properties of concrete. In: 22nd International Conference on Solid Waste Technology and Management (pp. 1386–1396). SiddiqueR. GuptaR. KaurI. 2007 Effect of spent foundry sand as partial replacement of fine aggregate on the properties of concrete In: 22nd International Conference on Solid Waste Technology and Management 1386 1396 Search in Google Scholar

[21] Singh, G., Siddique, R. (2012): Effect of waste foundry sand (WFS) as partial replacement of sand on the strength, ultrasonic pulse velocity and permeability of concrete. Construction and Building Materials, 26(1), pp. 416–422. SinghG. SiddiqueR. 2012 Effect of waste foundry sand (WFS) as partial replacement of sand on the strength, ultrasonic pulse velocity and permeability of concrete Construction and Building Materials 26 1 416 422 Search in Google Scholar

[22] Raval, A.D., Pamnani, A., Kachwala, A.I. (2015): Foundry sand: utilization as a partial replacement of fine aggregate for establishing sustainable concrete. International Journal of Engineering Sciences & Research Technology, 4(1), pp. 308–311. RavalA.D. PamnaniA. KachwalaA.I. 2015 Foundry sand: utilization as a partial replacement of fine aggregate for establishing sustainable concrete International Journal of Engineering Sciences & Research Technology 4 1 308 311 Search in Google Scholar

[23] Bilal, H., Yaqub, M., Rehman, S.K.U., Abid, M., Alyousef, R., Alabduljabbar, H., Aslam, F. (2019): Performance of foundry sand concrete under ambient and elevated temperatures. Materials, 12(16), p. 2645. BilalH. YaqubM. RehmanS.K.U. AbidM. AlyousefR. AlabduljabbarH. AslamF. 2019 Performance of foundry sand concrete under ambient and elevated temperatures Materials 12 16 2645 Search in Google Scholar

[24] Sebki, G., Safi, B., Chahour, K. (2019): Recycling of foundry sand wastes in self-compacting mortars: Use as cementitious materials and fine aggregates. Journal of Applied Engineering Sciences, 9(2), pp. 195–200. SebkiG. SafiB. ChahourK. 2019 Recycling of foundry sand wastes in self-compacting mortars: Use as cementitious materials and fine aggregates Journal of Applied Engineering Sciences 9 2 195 200 Search in Google Scholar

[25] García, R., De la Villa, R.V., Vegas, I., Frías, M., De Rojas, M.S. (2008): The pozzolanic properties of paper sludge waste. Construction and Building Materials, 22(7), pp. 1484–1490. GarcíaR. De la VillaR.V. VegasI. FríasM. De RojasM.S. 2008 The pozzolanic properties of paper sludge waste Construction and Building Materials 22 7 1484 1490 Search in Google Scholar

[26] Frías, M., Villar-Cociña, E., De Rojas, M.S., Valencia-Morales, E. (2005): The effect that different pozzolanic activity methods has on the kinetic constants of the pozzolanic reaction in sugar cane straw-clay ash/lime systems: Application of a kinetic–diffusive model. Cement and Concrete Research, 35(11), pp. 2137–2142. FríasM. Villar-CociñaE. De RojasM.S. Valencia-MoralesE. 2005 The effect that different pozzolanic activity methods has on the kinetic constants of the pozzolanic reaction in sugar cane straw-clay ash/lime systems: Application of a kinetic–diffusive model Cement and Concrete Research 35 11 2137 2142 Search in Google Scholar

[27] Okamura, H., Ozawa, K., Ouchi, M. (2000): Self-compacting concrete. Structural Concrete, 1(1), pp. 3–17. OkamuraH. OzawaK. OuchiM. 2000 Self-compacting concrete Structural Concrete 1 1 3 17 Search in Google Scholar

[28] ASTM C143/C143M-15a (2015): Standard Test Method for Slump of Hydraulic-Cement Concrete, ASTM International, West Conshohocken, PA. ASTM C143/C143M-15a 2015 Standard Test Method for Slump of Hydraulic-Cement Concrete ASTM International West Conshohocken, PA Search in Google Scholar

[29] ASTM International. (2019): ASTM C192/C192M-19, Standard Practice for Making and Curing Concrete Test Specimens in the Laboratory. Annual Book of ASTM Standards. ASTM International 2019 ASTM C192/C192M-19, Standard Practice for Making and Curing Concrete Test Specimens in the Laboratory Annual Book of ASTM Standards Search in Google Scholar