Stormwater Detention Tanks for Sustainable Energy Management in Urban Environment

Giuseppina Garofalo; Marco Carbone; Patrizia Piro

doi:10.4028/www.scientific.net/AMR.1073-1076.1031

Paper Titles

Application of Constructed Wetland to Rural Domestic Wastewater Treatment in China
p.1011

The Construction of Evaluation System for the Initial Rainwater Reduction Facilities in Shanghai
p.1017

Analysis of Security for Water Supply Network Based on the AHP Fuzzy Theory
p.1023

Research on Hydraulic Model Establishment of Water Supply Network
p.1027

Stormwater Detention Tanks for Sustainable Energy Management in Urban Environment
p.1031

Groundwater Quality Affected by Yellow River Irrigated Agriculture in Northern Suburb of Yinchuan, China
p.1035

Effectiveness of the Automation Selection of Water Treatment Technology in a Particular Water Source
p.1039

Research for Sustainable Development about Decentralized Reclaimed Water Project at City
p.1043

Discussion on Simulation Rotational Speed of Coagulation Jar Test
p.1047

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 1073-1076Stormwater Detention Tanks for Sustainable Energy...

Stormwater Detention Tanks for Sustainable Energy Management in Urban Environment

Abstract:

The risk of flooding in urban environment has become more and more frequent due to the increased impervious surfaces and climate change. The most suitable solutions for mitigating the urban flooding risks are stormwater detention tanks which temporarily store the exceeded rainfall and gradually release it into the urban drainage system at the end of the rainfall events. The present study aims to evaluate the feasibility of stormwater detention tanks used also for producing hydroelectric power serving a small town, through the release of such volumes. The study is applied to an urban watershed in the city of Cosenza, Italy. After a preliminary design, a hydrologic/hydraulic model, SWMM, coupled with a numerical model implemented in MATLAB was used to predict the stormwater volumes reusable for the production of electricity and the overall response of the system on annual basis. The results obtained showed that a mini-hydro system in an urban area is technically feasible. From an economic point of view, the system is self-sustainable only if one considers the need to integrate the urban drainage network with the electric power grid using the stormwater volumes to store energy in hours of maximum electric energy production that otherwise would be lost.

You might also be interested in these eBooks

Environmental Protection and Resource Utilization IV

View Preview

Info:

Periodical:

Advanced Materials Research (Volumes 1073-1076)

Pages:

1031-1034

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1073-1076.1031

Citation:

Cite this paper

Online since:

December 2014

Authors:

Giuseppina Garofalo*, Marco Carbone, Patrizia Piro

Keywords:

Electric Power, Mini-Hydro, Urban Drainage Systems

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] Belli, G., Burgio, A., Brusco, G., Menniti, D., Pinnarelli, A., Sorrentino, N., (2014). A power management control with grid-ancillary services for a Smart User Network, submitted to IEEE Transactions General Meeting.

DOI: 10.1109/afrcon.2013.6757763

Google Scholar

[2] Piro, P., Carbone, M., Garofalo, G., &Sansalone, J. (2010). Management of CSOs based on observations from the urbanized Liguori catchment of Cosenza, Italy. Water Science & Technology, 61(1), 135-143.

DOI: 10.2166/wst.2010.805

Google Scholar

[3] Piro, P., Carbone, M., Garofalo, G., &Sansalone, J. (2010). Size Distribution of Wet Weather and Dry Weather Particulate Matter Entrained in Combined Flows from an Urbanizing Sewershed. Water, air, and soil pollution, 206(1-4), 83-94.

DOI: 10.1007/s11270-009-0088-7

Google Scholar

[4] Piro, P., Carbone, M., &Sansalone, J. (2012). Delivery and frequency distributions of combined wastewater collection system wet and dry weather loads. Water Environment Research, 84(1), 65-75.

DOI: 10.2175/106143011x13188633467111

Google Scholar

[5] Exall, K., Marsalek, J., & Schaefer, K. (2004). A review of water reuse and recycling, with reference to Canadian practice and potential: 1. Incentives and implementation. Water Quality Research Journal of Canada, 39(1), 1-12.

DOI: 10.2166/wqrj.2004.003

Google Scholar

[6] Hatt, Belinda E., Deletic, A., and Fletcher, T. D. (2006). Integrated treatment and recycling of stormwater: a review of Australian practice. Journal of environmental management 79(1), 102-113.

DOI: 10.1016/j.jenvman.2005.06.003

Google Scholar

[7] Lahimer, A. A., Alghoul, M. A., Yousif, F., Razykov, T. M., Amin, N., &Sopian, K. (2013) Research and development aspects on decentralized electrification options for rural household. Renewable and Sustainable Energy Reviews, 24, 314-324.

DOI: 10.1016/j.rser.2013.03.057

Google Scholar

[8] Paish, O. (2002) Small hydro power: technology and current status. Renewable and sustainable energy reviews, 6(6), 537-556.

DOI: 10.1016/s1364-0321(02)00006-0

Google Scholar