Use of Recycled Materials in the Manufacture of Porous Concrete to Remove TOC from Municipal Runoff

Document Type : Applied Article

Authors

1 MSc, Faculty of Civil Engineering, Water and Environment, Shahid Beheshti University, Tehran, Iran

2 Assistant Professor, Faculty of Civil Engineering, Water and Environment, Shahid Beheshti University, Tehran, Iran

Abstract

Purifier porous concrete as a new technology in the development of urban areas for the controlling and physical treatment of runoff has been considered in many industrialized countries in recent years. The use of recycled compounds in the manufacture of concrete in order to reduce the pressure on natural resources and also lower the carbon dioxide generation for environmental preservation and sustainable development is the main challenge of the civil industry. In this study, two types of recycled ceramic and crushed concrete aggregates and one type of pumice aggregate with pozzolanic properties were used to make porous concrete to achieve the study’s goals and necessity. Six mixing plans were designed with high priority of permeability, sufficient strength, and suitable filtration. Mechanical properties including adsorption, density, porosity, permeability, and compressive strength and treatment efficiency (TOC removal) tests were performed on concrete samples. The results of studies showed that the use of pumice up to 25% replacement with recycled construction materials increased the porosity and permeability of concrete by 13 and 43%, respectively, and its density and compressive strength decreased by 12.5 and 39%, respectively, compared to the control sample. In the view of the removal of TOC, a 13% increase in yield was observed for the sample with a 25% replacement of pumice. The outstanding performance of the mixing plan containing pumice aggregates in mechanical strength and treatability can be considered a new approach to the use of recycled materials in the development and construction of urban areas.

Keywords

Main Subjects

References

Afshar N.R. and Fahmi H. 2019. Impact of climate change on water resources in Iran. International Journal of Energy and Water Resources, 3: 55-60.
Al Ghussain L. 2019. Global warming: review on driving forces and mitigation. Environmental Progress & Sustainable Energy, 38: 13-21.
AlShareedah O. and Nassiri S. 2020. Pervious concrete mixture optimization, physical, and mechanical properties and pavement design: A review. Journal of Cleaner Production, 125095.
Brattebo, B.O., Booth, D.B., 2003. Long-term stormwater quantity and quality performance of permeable pavement systems. Water research, 37: 4369-4376.
Chan Y., Luo X. and Sun W. 2000. Compressive strength and pore structure of high-performance concrete after exposure to high temperature up to 800 C. Cement and Concrete Research, 30: 247-251.
Chang J.J., Yeih W., Chung T. and Huang R. 2016. Properties of pervious concrete made with electric arc furnace slag and alkali-activated slag cement. Construction and Building Materials, 109: 34-40.
Delatte N. 2018. Concrete pavement design, construction, and performance. Crc Press.
Duan P., Hu X., Ji Z., Yang X. and Sun Z. 2018. Enhanced oxidation potential of Ti/SnO2-Cu electrode for electrochemical degradation of low-concentration ceftazidime in aqueous solution: Performance and degradation pathway. Chemosphere, 212: 594-603.
EPA. 2010. Preparing Your Drinking Water Consumer. Environmental Protection Agency, Washington DC.
Ibrahim H.A. and Razak H.A. 2016. Effect of palm oil clinker incorporation on properties of pervious concrete. Construction and Building Materials, 115: 70-77.
Liu W., Chen W., Feng Q., Peng C. and Kang P. 2016. Cost-benefit analysis of green infrastructures on community stormwater reduction and utilization: a case of Beijing, China. Environmental management, 58: 1015-1026.
Lori A.R., Hassani A. and Sedghi R. 2019. Investigating the mechanical and hydraulic characteristics of pervious concrete containing copper slag as coarse aggregate. Construction and Building Materials, 197: 130-142.
Muthu M., Santhanam M. and Kumar M. 2018. Pb removal in pervious concrete filter: effects of accelerated carbonation and hydraulic retention time. Construction and Building Materials, 174: 224-232.
Nassiri S. 2020. Development of Protocol to Maintain Winter Mobility of Different Classes of Pervious Concrete Pavement Based on Porosity. Final Report. Washington State University.
Nnadi E.O., Newman A.P., Coupe S.J. and Mbanaso F.U. 2015. Stormwater harvesting for irrigation purposes: An investigation of chemical quality of water recycled in pervious pavement system. Journal of environmental management, 147: 246-256.
Office U.S.E.P.A.T.I. and Support E.M. 1999. Field applications of in situ remediation technologies: Permeable reactive barriers. DIANE Publishing.
Pratt C., Mantle J. and Schofield P. 1989. Urban stormwater reduction and quality improvement through the use of permeable pavements. Urban discharges and receiving water quality impacts. Elsevier, 123-132.
Shabalala A.N. and Ekolu S.O. 2019. Assessment of the suitability of mine water treated with pervious concrete for irrigation use. Mine Water and the Environment, 38: 798-807.
Shabalala A.N., Ekolu S.O., Diop S. and Solomon F. 2017. Pervious concrete reactive barrier for removal of heavy metals from acid mine drainage− column study. Journal of Hazardous Materials 323: 641-653.
Shang H. and Sun Z. 2018. PAHs (naphthalene) removal from stormwater runoff by organoclay amended pervious concrete.
Visco G., Campanella L. and Nobili V. 2005. Organic carbons and TOC in waters: an overview of the international norm for its measurements. Microchemical Journal, 79: 185-191.
Wicke D., Matzinger A., Sonnenberg H., Caradot N., Schubert R.L., Dick R., Heinzmann B., Dünnbier U., von Seggern D. and Rouault P. 2021. Micropollutants in Urban Stormwater Runoff of Different Land Uses. Water, 13: 1312.
Yadollahie M. 2019. The flood in Iran: a consequence of the global warming? The international journal of occupational and environmental medicine, 10: 54.
Yoo J., Shin H. and Ji S. 2018. Evaluation of the applicability of concrete sludge for the removal of Cu, Pb, and Zn from contaminated aqueous solutions. Metals, 8: 666.
Zhang R., Kanemaru K. and Nakazawa T. 2015. Purification of river water quality using precast porous concrete products. Journal of advanced concrete technology, 13: 163-168.
Zhang Z., Zhang Y., Yan C. and Liu Y. 2017. Influence of crushing index on properties of recycled aggregates pervious concrete. Construction and Building Materials, 135: 112-118.
Send comment about this article
CAPTCHA Image

Files

History

  • Receive Date: 03 October 2021
  • Revise Date: 14 December 2021
  • Accept Date: 20 December 2021

Share

How to cite

Statistics