Vol. 13 No. 02 (2023): Journal of Materials and Construcstion
##common.pageHeaderLogo.altText##
JOURNAL OF MATERIALS & CONSTRUCTION

ISSN: 2734-9438

Website: www.jomc.vn

Geopolymer pervious concrete with recycled Coal Bottom Ash (CBA) and Ground Granulated Blast furnace (GGBF) slag in urban flooding solution

Duc Hung Phan , Anh Tuan Le , Tan Khoa Nguyen

Keywords:

Pervious concrete
Geopolymer
Coal bottom ash
Ground Granulated Blast furnace slag
Permeability
Porosity

Abstract

Pervious concrete is known as a high content formation of open void to allow for fast drainage of water. The main compositions of pervious concrete are coarse aggregate and binder to obtain a high volume of hollow area. In this research, the coal bottom ash (CBA) is used as coarse aggregate in mix proportion. Ground Granulated Blast furnace (GBBF) slag is used geopolymer binder to replace cement in geopolymer pervious concrete (GPC). They are known as waste industrial materials from thermal power plant and steel factory. The characteristics of geopolymer pervious concrete in compressive strength, porosity and permeability are considered. The reaction between GGBF slag and CBA is investigated. The results are shown that compressive strength GPC is about 2 MPa to 8 MPa with CBA 5 mm to 10mm and can be higher about 30 % to 40 % with CBA 10 mm to 20 mm. The water permeability is about 0.7 cm/s to 1.8 cm/s to belong to CBA type

User Navigation

PDF

How to Cite

Phan, D. H., Le, A. T., & Nguyen, T. K. (2023). Geopolymer pervious concrete with recycled Coal Bottom Ash (CBA) and Ground Granulated Blast furnace (GGBF) slag in urban flooding solution. JOURNAL OF MATERIALS & CONSTRUCTION, 13(02), Page 20 – Page 23. https://doi.org/10.54772/jomc.v13i02.558

References

  1. . Tu, T.T. and Nitivattananon, V. (2011). Adaptation to flood risks in Ho Chi Minh City Vietnam. International Journal of Climate Change Strategies and Management, 3(1):61-73.
  2. . Storch, H. et al. (2016). Adaptation: Integrative Planning Framework for Adapted Land-Use Planning. In Sustainable Ho Chi Minh City: Climate Policies for Emerging Megacities, 51-74, Springer.
  3. . Khiem, V.M, et al. (2017). Impact of Climate Change on Intensity-Duration-Frequency Curves in Ho Chi Minh City, Journal of Climate Change Science, 3:40-48.
  4. . IPCC: Climate Change 2022, (2022). Impacts, Adaptation, and Vulnerability, Contribution of Working Group II to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change, Cambridge University Press.
  5. . Awoyera, P., Adesina, A. (2019). A critical review on application of alkali activated slag as a sustainable composite binder”, Case Study Construction Material, 11:e00268.
  6. . Chippagiri, R. et al. (2021). Application of sustainable prefabricated wall technology for energy efficient social housing”. Sustain, 13(3):1-12.
  7. . Hassan, A., Arif, M., Shariq, M. (2019). Use of geopolymer concrete for a cleaner and sustainable environment - A review of mechanical properties and microstructure, Journal of Cleaner Prododuction, 223:704-728.
  8. . Qaidi S. (2022). Ultra-High-Performance Geopolymer Concrete. Part 6: Mechanical Properties, University of Duhok, Iraq.
  9. . Zhou, H. et al. (2022). Towards sustainable coal industry: Turning coal bottom ash into wealth, Science of the Total Environment, 804, Article No. 149985.
  10. . Zhong R., Wille K. (2015). Material design and characterization of high performance pervious concrete, Construction and Building Materials, 98(9):51-60.
  11. . Japan Concrete Institute (JCI), Construction and recent applications of porous concrete, Proc. of the JCI symposium on design, 1-10.
  12. . ACI 522R-10, (2010). Report on Pervious Concrete, American Concrete Institute (ACI).