Municipal solid waste incineration ashes and their potential for partial replacement of Portland cement and fine aggregates in concrete
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Department of Materials Engineering and Chemistry, Faculty of Civil Engineering, Czech Technical University in Prague, Czech Republic
Experimental Center, Faculty of Civil Engineering, Czech Technical University in Prague, Czech Republic
Publication date: 2010-07-01
Cement Wapno Beton 15(4) 187-193 (2010)
The work has been supported b y fi nancial mechanisms of EEA and Norway, under grant No A/CZ0046/1/0027.
E. E. Berry, V. M. Malhotra, Fly-ash for use in concrete - a critical-review. Journal of the American Concrete Institute 77, 59-73 (1980).
P. Chindaprasirt, C. Chotithanorm, H. T. Cao, V. Sirivivatnanon, Infl uence of fl y ash fi neness on the chloride penetration of concrete. Construction and Building Materials 21, 356–361 (2007). J. Małolepszy, E. Tkaczewska, Effect of fl y ash fi neness on the fly ash cement hydration and properties. Cement Wapno Beton 12/74, 297-302 (2007).
J. M. Khatib, Performance of self-compacting concrete containing fl y ash. Construction and Building Materials 22, 1963–1971 (2008).
J. Bensted, J. R. Smith, Oilwell cements part 5: applications of fl y ash in well cementing. Cement Wapno Beton 13/75, 17-30 (2008).
P. Dinakar, K. G. Babu, M. Santhanam, Durability properties of high volume fl y ash self compacting concretes. Cement and Concrete Composites 30, 880–886 (2008).
H. Yazici, The effect of silica fume and high-volume Class C fl y ash on mechanical properties, chloride penetration and freeze-thaw resistance of self-compacting concrete. Construction and Building Materials 22, 456-462 (2008).
E. Tkaczewska, J. Małolepszy, Effect of the fl y ash fi neness on the sulphate resistance off fl y ash cement. Cement Wapno Beton 14/76, 26-33 (2009).
E. Vejmelková, M. Pavlíková, M. Keppert, Z. Keršner, P. Rovnaníková, M. Ondráček, M. Sedlmajer, R. Černý, Fly-Ash Infl uence on the Properties of High Performance Concrete. Cement Wapno Beton 13/75, 189-204 (2009).
L. Bertolini, M. Carsana, D. Cassago, A.Q. Curzio, M. Collepardi, MSWI ashes as mineral additions in concrete. Cement and Concrete Research 34, 1899–1906 (2004).
J. Pera, L. Coutaz, J. Ambroise, M. Chababbet, Use of Incinerator Bottom Ash in Concrete. Cement and Concrete Research 27, 1–5 (1997).
K. L. Lin, K. S. Wang, B. Y. Tzeng, C. Y. Lin, The Reuse of Municipal Solid Waste Incinerator Fly Ash Slag as a Cement Substitute. Resources Conservation & Recycling 39, 315–324 (2003).
U. Müller, K. Rübner, The Microstructure of Concrete Made with Municipal Waste Incinerator Bottom Ash as an Aggregate Component. Cement and Concrete Research 36, 1434–1443 (2006).
X. Gao, W. Wang, T. Ye, F. Wang, Y. Lan, Utilization of Washed MSWI Fly Ash as Partial Cement Substitute with the Addition of Dithiocarbamic Chelate. Journal of Environmental Management 88, 293–299 (2008).
M. Ferraris, M. Salvo, A. Ventrella, L. Buzzi, M. Veglia, Use of Vitrifi ed MSWI Bottom Ashes for Concrete Production. Waste Management 29, 1041–1047 (2009).
T.-C. Lee, M.-K. Rao, Recycling Municipal Incinerator Fly and Scrubber Ash into Fused Slag for the Substantial Replacement of Cement in Cement Mortars. Waste Management 29, 1952 – 1959 (2009).
ČSN EN 12390-1. Testing of settled concrete – Part 1: Shape, dimensions and other requirement on specimens and moulds. European Committee for Standardization.
ČSN EN 12350-2. “Testing of fresh concrete – Part 2: Slump test.“ European Committee for Standardization.
ČSN EN 12390-3. “Testing of settled concrete – Part 3: Compressive strength.“ European Committee for Standardization.
ČSN EN 12620. “Aggregates for concrete.” European Committee for Standardization.
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