[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/cac.2016.17.6.787

A study of the fresh properties of Recycled ready-mixed soil materials (RRMSM)

Huang, Wen-Ling (Department of Civil Engineering, National Kaohsiung University of Applied Sciences)
Wang, Her-Yung (Department of Civil Engineering, National Kaohsiung University of Applied Sciences)
Chen, Jheng-Hung (Department of Civil Engineering, National Kaohsiung University of Applied Sciences)

Publication Information

Computers and Concrete / v.17, no.6, 2016 , pp. 787-799 More about this Journal

Abstract

Climate anomalies in recent years, numerous natural disasters caused by landslides and a large amount of entrained sands and stones in Taiwan have created significant disasters and greater difficulties in subsequent reconstruction. How to respond to these problems efficaciously is an important issue. In this study, the sands and stones were doped with recycled materials (waste LCD glass sand, slag powder), and material was mixed for recycled ready-mixed soil. The study is based on security and economic principles, using flowability test to determine the water-binder ratio (W/B=2.4, 2.6, and 2.8), a fixed soil: sand ratio of 6:4 and a soil: sand: glass ratio of 6:2:2 as fine aggregate. Slag (at concentrations of 0%, 20%, and 40%) replaced the cement. The following tests were conducted: flowability, initial setting time, unit weight, drop-weight and compressive strength. The results show that the slump values are 220 -290 mm, the slump flow values are 460 -1030 mm, and the tube flow values are 240-590 mm, all conforming to the objectives of the design. The initial setting times are 945-1695 min. The unit weight deviations are 0.1-0.6%. The three groups of mixtures conform to the specification, being below 7.6 cm in the drop-weight test. In the compressive strength test, the water-binder ratios for 2.4 are optimal ( $13.78-17.84kgf/cm^2$ ). The results show that Recycled ready-mixed soil materials (RRMSM) possesses excellent flowability. The other properties, applied to backfill engineering, can effectively save costs and are conducive to environmental protection.

Keywords

Recycled Ready-Mixed Soil Materials (RRMSM); waste LCD glass sand; waste-to-resource;

Citations & Related Records

Times Cited By KSCI : 1 (Citation Analysis)

Reference
Cited By KSCI

1	ASTM D 6023, Standard Test Method for Unit Weight, Yield, Cement Content, and Air Content (Gravimetric) of Controlled Low Strength Material (CLSM).
2	ASTM D 6024, ASTM D6024 Standard Test Method for Ball Drop on Controlled Low Strength Material (CLSM) to Determine Suitability for Load Application.
3	ASTM D 6103, Standard Test Method for Flow Consistency of Controlled Low Strength Material (CLSM).
4	Chen, J.W. and Chang, C.F. (2003), "Development and application of the ready-mixed soil material", Proceedings of the 14th International Society of Offshore and Polar Engineering Conference (ISOPE), Toulon France.
5	CNS 12549, Concrete and cement plaster material ballast water quenched blast furnace dust.
6	Katz, A. and Kovler, K. (2004), "Utilization of industrial by-products for the production of controlled low strength materials (CLSM)", Waste Manage., 24(5), 501-512. DOI
7	Khatib, J.M. (2005), "Properties of concrete incorporating fine recycled aggregate", Cement Concrete Res., 35(4), 763-769. DOI
8	Lee, S.T., Moon, H.Y., Swamy, R.N., Kim, S.S. and Kim, J.P. (2005), "Sulfate attack of mortars containing recycled fine aggregates", ACI Mater. J., 102(4), 224-230.
9	Lachemi, M., Hossain, K.M., Shehata, M. and Thaha, W. (2007), "Characteristics of controlled low-strength materials incorporating cement kiln dust", Can. J. Civil Eng., 34(4), 485-495. DOI
10	Mejeoumov, G.G., Shon, C.S., Saylak, D. and Estakhri, C.K. (2010), "Potential use of stockpiled circulating fluidized bed combustion ashes in controlled low strength material (CLSM) mixture", Constr. Build. Mater., 24(5), 839-847. DOI
11	Nataraja, M.C. and Nalanda, Y. (2008), "Performance of industrial by-products in controlled low-strength materials (CLSM)", Waste Manage., 28(7), 1168-1181. DOI
12	Naik, T.R., Singh, S.S. and Ramme, B.W. (2001), "Performance and leaching assessment of flowable slurry", J. Envir. Eng., 127(4), 359-368. DOI
13	Naik, T.R., Kraus, R.N. and Siddique, R. (2003), "Controlled low-strength materials containing mixtures of coal ash and new pozzolanic material", ACI Mater. J., 100(3), 208-215.
14	Naik, T.R., Kraus, R.N., Ramme, B.W., Chun, Y.M. and Kumar, R. (2006), "High-carbon fly ash in manufacturing conductive CLSM and concrete", J. Mater. Civil Eng., 18(6), 743-746. DOI
15	Naganathan, S., Razak, H.A. and Hamid, S.N.A. (2012), "Properties of controlled low-strength material made using industrial waste incineration bottom ash and quarry dust", Mater. Des., 33, 56-63. DOI
16	Pierce, C.E. and Blackwell, M.C. (2003), "Potential of scrap tire rubber as lightweight aggregate in flowable fill", Waste Manage., 23(3), 197-208. DOI
17	Pierce, C.E., Tripathi, H. and Brown, T.W. (2003), "Cement kiln dust in controlled low-strength materials", ACI Mater. J., 100(6), 455-462.
18	Siddique, R. (2009), "Utilization of waste materials and by-products in producing controlled low-strength materials", Resour. Conserv. Recy., 54(1), 1-8. DOI
19	Razak, H.A., Naganathan, S. and Hamid, S.N.A. (2009), "Performance appraisal of industrial waste incineration bottom ash as controlled low-strength material", J. Hazard. Mater., 172(2), 862-867. DOI
20	Rahal, K. (2007), "Mechanical properties of concrete with recycled coarse aggregate", Build. Envir., 42(1), 407-415. DOI
21	Siddique, R. (2009), "Utilization of waste materials and by-products in producing controlled low-strength materials", Resour. Conserv. Recy., 54(1), 1-8. DOI
22	Terro, M.J. (2006), "Properties of concrete made with recycled crushed glass at elevated temperatures", Build. Envir., 41(5), 633-639. DOI
23	Tu, T.Y., Chen, Y.Y. and Hwang, C.L. (2006), "Properties of HPC with recycled aggregates", Cement Concrete Res., 36(5), 943-950. DOI
24	Topcu, I.B. and Canbaz, M. (2004), "Properties of concrete containing waste glass", Cement Concrete Res., 34(2), 267-274. DOI
25	Tong, C.C. (2007), "A study of the impact and damaging behaviors of adding polypropylene fiber into ready-mixed soil material", the achievement report of a specific research project of the National Science Council, the Executive Yuan.
26	Tikalsky, P.J., Bahia, H.U., Deng, A. and Snyder, T. (2004), "Excess foundry sand characterization and experimental investigation in controlled low-strength material and hot-mixing asphalt (No. DE-FC36-01ID13974)", The Pennsylvania State University/Pennsylvania Transportation Institute.
27	Turkel, S. (2006), "Long-term compressive strength and some other properties of controlled low strength materials made with pozzolanic cement and Class C fly ash", J. Hazard. Mater., 137(1), 261-266. DOI
28	Turkel, S. (2007), "Strength properties of fly ash based controlled low strength materials", J. Hazard. Mater., 147(3), 1015-1019. DOI
29	Tseng, C.C. (2009), "Competitiveness analysis of display panel industry in Taiwan and Korea (II)", Quality magazine is published by the Chinese society for quality, 45(2), 48-52.
30	Wang, H.Y. and Huang, W.L. (2010), "Durability of self-consolidating concrete using waste LCD glass", Constr. Build. Mater., 24(6), 1008-1013. DOI
31	Wang, H.Y. and Chen, J.S. (2008), "Study of thin film transition liquid crystal display (TFT-LCD) optical waste glass applied in early-high-strength controlled low strength materials", Comput. Concrete, 5(5), 491-501. DOI
32	ASTM C33, Standard Specification for Concrete Aggregates.
33	Achtemichuk, S., Hubbard, J., Sluce, R. and Shehata, M.H. (2009), "The utilization of recycled concrete aggregate to produce controlled low-strength materials without using Portland cement", Cement Concrete Compos., 31(8), 564-569. DOI
34	ACI 229R- 99, Controlled Low-strength Material (CLSM), ACI Committee.
35	ASTM D6103, Standard Test Method for Flow Consistency of Controlled Low Strength Material(CLSM).
36	ASTM C39, Standard Test Method for Compressive Strength of Cylindrical Concrete Specimens.
37	ASTM C143, Standard Test Method for Slump of Cement Concrete.
38	ASTM C150, American Society for Testing and Materials, Standard Specification for Portland cement.
39	ASTM C1602, Standard Specification for Mixing Water Used in the Production of Hydraulic Cement Concrete.
40	ASTM C403, Standard Test Method for Time of Setting of Concrete Mixtures by Penetration Resistance.