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Generalized strength development model of solidified fine-grained dredged marine soils

Chan, Chee-Ming and Azhar, Amira (2015) Generalized strength development model of solidified fine-grained dredged marine soils. In: First International Conference on Science, Engineering & Environment, 19-21 November 2015, Tsu City, Mie, Japan.

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Abstract

Dredged marine soils (DMS) are the sediment and debris removed in the dredging process. Large amount of DMS is generated from the dredging operations yearly, especially from the maintenance of existing shipping channels and the development of various coastal infrastructures. In practice, DMS are generally disposed of at designated offshore dump sites. Inadvertently, these discarded DMS would in time be deposited back near shore due to tidal dynamics, necessitating dredging works again. Considering that DMS are essentially soils with poor engineering properties, particularly low shear strength, there could be potential for the materials’ reuse as acceptable or good geomaterials if the original conditions can be improved. Pre-treatment for enhancement of the soil’s strength, such as solidification, is a feasible option. In the present study, the solidification of 3 DMS samples was examined with the admixing of cement and/or bottom ash, where cement acts as a binder while the bottom ash functions a filler material to lend structure to the weak soil. The strength improvement of the solidified DMS was monitored with the unconfined compression tests. The key factors that influence strength development in solidified soils were investigated, i.e. curing period, water-binder ratio and binder-filler mix ratio. The curing period was prefixed at 3, 7, 14, 28 and 56 days, while the water-binder ratio examined were 1, 3 and 5. The test results indicated that strength increased with curing time and higher water-binder ratio. The optimal binder-filler mix ratio determined was 75 % cement to 25 % bottom ash. The bottom ash was found to contribute to strength gain too, albeit in a minor way compared to the highly reactive cement. For the generalized strength development plots, the unconfined compressive strength of a particular day (q) was divided with the strength on day 28 (q28). The resulting q/q28 vs. curing period plots were linear with varying gradients dependent on the water-binder ratio, though it was apparent that the gradient of the plot decreased with increased water-binder ratio. In summary, solidification with cement-bottom ash is expedient in improving the original low strength of the DMS, and the generalized strength development model is useful for modeling, design and prediction on site

Item Type: Conference or Workshop Item (Paper)
Uncontrolled Keywords: dredged marine soils; solidification; water-binder ratio; cement; bottom ash; strength development
Subjects: T Technology > TA Engineering (General). Civil engineering (General) > TA703-711 Engineering geology. Rock mechanics. Soil mechanics.
Divisions: Faculty of Engineering Technology > Department of Civil Engineering Technology
Depositing User: Mrs. Nurhayati Ali
Date Deposited: 31 Jan 2016 06:36
Last Modified: 31 Jan 2016 06:36
URI: http://eprints.uthm.edu.my/id/eprint/7514
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