Vol. 11 No. 02 (2021): Journal of Materials & Construcstion
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JOURNAL OF MATERIALS & CONSTRUCTION

ISSN: 2734-9438

Website: www.jomc.vn

Experimental studies on hydraulic conductivity of different straw fiber cement treated mud

Chien Phan Thanh

Keywords:

Rice straw
Hydraulic conductivity
Composite mud
Falling head test
Cement mud

Abstract

Hydraulic conductivity characteristics of mud treated by rice straw fiber and cement were investigated by falling head permeability tests. The experimental results indicated that the water conductivity significantly decreased by the inserting of either cement or rice straw fiber. Comparing with cement-treated mud, the addition of rice straw fiber considerably reduced the water conductivity of the mud composite. Moreover, empirical equations were revealed to predict the value of hydraulic conductivity for the modified-mud.

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How to Cite

Phan Thanh, C. (2021). Experimental studies on hydraulic conductivity of different straw fiber cement treated mud. JOURNAL OF MATERIALS & CONSTRUCTION, 11(02), Page 8 – Page 12. https://doi.org/10.54772/jomc.v11i02.285

References

  1. . P. T. Chien, T. Satomi, and H. Takahashi (2007). Study on sludge recycling with compaction type and placing type by rice husk-cement-stabilized soil method. Advanced Experimental Mechanics, (2):159-167.
  2. . M. Mori and H. Takahashi (2003). A proposal of new recycling system for high-water content muds by using paper debris and polymer and strength property of recycled soils. Journal of MMIJ, (119):155-160.
  3. . H. Takahashi (2014). Topical Themes in Energy and Resources. Springer: Tokyo Heidelberg New York Dordrecht London.
  4. . H. Takahashi and M. Mori (2012). Creation of artificial ground by recycling tsunami sludge. Proceedings of the 6th Symposium on Sediment-Related Disasters, Japan.
  5. . M. Mori, H. Takahashi, and K. Kumakura (2006). An experimental study on strength of fiber-cement-stabilized mud by use of paper sludge and durability for drying and wetting tests. Journal of MMIJ, (122):353-361.
  6. . TheWorldBank (2012). Mekong Delta Transport Infrastructure Development Project.
  7. . S. N. Tran and K. Ingvorsen (2014). To quantify the seasonal rice straw and its use in different provinces in the Vietnamese Mekong Delta. Can Tho University Journal of Science, (32):87-93.
  8. . S. M. Hejazi, M. Sheikhzadeh, S. M. Abtahi, and A. Zadhoush (2012). A simple review of soil reinforcement by using natural and synthetic fibers. Construction and Building Materials, (30):100-116.
  9. . R. MacVicar (1997). Mechanical and physical changes associated with aging of cellulose fiber reinforced cement composites. University of Toronto.
  10. . H. W. Xiao and S. Y. Yeoh (2013). Fiber Reinforced Cement Treated Clay. Proceedings of the 18th International Conference on Soil Mechanics and Geotechnical Engineering, Paris.
  11. . A. M. Brandt (2008). Fibre reinforced cement-based (FRC) composites after over 40 years of development in building and civil engineering. Composite Structures, (86):3-9.
  12. . M. Maher and Y. Ho (1993). Behavior of fiber-reinforced cemented sand under static and cyclic loads. Geotechnical Testing Journal, (16):330-338.
  13. . N. Consoli and L. A. Ulbrich (1998). Influence of Fiber and Cement Addition on Behavior of Sandy Soil. Journal of Geotechnical and Geoenvironmental Engineering, (124):1211-1214.
  14. . P. T. Chien, T. Satomi, and H. Takahashi (2018). Study on strength characteristics of rice straw fiber-cement-reinforced sludge. International Journal of the Society of Materials Engineering for Resources, (23):147-151.