Abstract
In this study, a dynamic numerical model was developed to examine catchment-scale wastewater management, including urban household wastewater treatment. The model allowed both water quality and energy consumption to be evaluated. This system was applied to an actual sewerage system, and the effects of management strategies on water quality and energy consumption were assessed in a numerical simulation. The entire water resource system of a basin, including a forest catchment and an urban area, was evaluated synthetically from a spatial distribution perspective with respect to water quantity and quality. The life-cycle assessment technique was applied to optimize wastewater treatment management with the aim of improving water quality and reducing CO2 emissions. A numerical model was developed to predict the water cycle and contamination in the catchment and the city; the effect of a wastewater treatment system on the urban region was evaluated; pollution loads were quantitatively assessed; and the effect of excluding rainwater from the treatment system during flooding and the effect of urban rainwater control on water quality were examined. Analysis indicated that controlling the amount of rainwater inflow into a wastewater treatment plant in an urban area with a combined sewerage system has a large impact on reducing CO2 emissions because of the load reduction on the urban sewerage system.
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References
Chia, S. S., & Defilippi, J. A. (1970). System optimization of waste treatment plant process design. Journal of Environmental Engineering Division ASCE, 96, 409–421.
Entem, S., Lahoud, A., Yde, L., & Bendsen, B. (1998). Real time control of the sewer system of Boulogne Billancourt—A contribution to improving the water quality of the Seine. Water Science and Technology, 37(1), 327–332.
Ichinose, T., Hanaki, K., Ito, T., Matsuo, T., & Kawahara, H. (1997). Feasibility study on district heating system based on combination between geographic information systems and life cycle assessment. Journal of Environmental Science, 10(2), 119–127.
JSWA, Japan Sewage Works Association. (2004). Sewerage statistics 2004.
Mouri, G., & Oki, T. (2010a). Modelling the catchment-scale environmental impacts of wastewater treatment in an urban sewage system for CO2 emission assessment. Water Science and Technology, 62(4), 972–984.
Mouri, G., & Oki, T. (2010b). Modelling sewer sediment deposition, erosion, and transport processes to predict acute influent and reduce combined sewer overflows and CO2 emissions. Water Science and Technology, 62(10), 2346–2356.
Mouri, G., Shinoda, S., & Oki, T. (2013a). Assessment of the historical environmental changes from a survey of local residents in an urban–rural catchment. Ecological Complexity, 15C, 83–96.
Mouri, G., Takizawa, S., Fukushi, K., & Oki, T. (2013b). Estimation of the effects of chemically-enhanced treatment of urban sewage system based on life- cycle management. Sustainable Cities and Society, 9C, 23–31.
Petruck, A., Cassar, A., & Dettmar, J. (1998). Advanced real time control of a combined sewer system. Water Science and Technology, 37(1), 319–326.
Schutze, M., Butler, D., & Bruce Beck, M. (1999). Optimization of control strategies for the urban wastewater system—An integrated approach. Water Science and Technology, 39(9), 209–216.
Shih, C. S. (1970). System optimization for river basin water quality management. Journal of the Water Pollution Control Federation, 42(10), 1792–1804.
Vanrolleghem, P., Benedetti, L., & Meirlaen, J. (2005). Modeling and real-time control of the integrated urban wastewater system. Environmental Modelling and Software, 20, 427–442.
Acknowledgments
This study was supported by funding from the New Energy and Industrial Technology Development Organization (NEDO), the Environmental Research and Technology Development Fund (S-8) of the Ministry of the Environment of Japan, the Green Network of Excellence (GRENE), the Sumitomo Foundation, the Foundation of River and Watershed Environment Management, Grants-in-Aid for Scientific Research (24560616) from the Ministry of Education of Japan, and Core Research for Evolutionary Science and Technology (CREST) of Japan. The data were partially provided by the Shikoku Regional Bureau of MLIT, and we are grateful for their support.
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Mouri, G., Oki, T. (2017). Catchment-Scale Water Management of Wastewater Treatment in an Urban Sewerage System with CO2 Emission Assessment. In: Yokohari, M., Murakami, A., Hara, Y., Tsuchiya, K. (eds) Sustainable Landscape Planning in Selected Urban Regions. Science for Sustainable Societies. Springer, Tokyo. https://doi.org/10.1007/978-4-431-56445-4_13
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DOI: https://doi.org/10.1007/978-4-431-56445-4_13
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