Sara Nazif scite author profile

A technique for leakage reduction is pressure management, which considers the direct relationship between leakage and pressure. To control the hydraulic pressure in a water distribution system, water levels in the storage tanks should be maintained as much as the variations in the water demand allows. The problem is bounded by minimum and maximum allowable pressure at the demand nodes. In this study, a Genetic Algorithm (GA) based optimization model is used to develop the optimal hourly water level variations in a storage tank in different seasons in order to minimize the leakage level. Resiliency and failure indices of the system have been considered as constraints in the optimization model to achieve the minimum required performance. In the proposed model, the results of a water distribution simulation model are used to train an Artificial Neural Network (ANN) model. Outputs of the ANN model as a hydraulic pressure function is then linked to a GA based optimization model to simulate hydraulic pressure and leakage at each node of the water distribution network based on the water level in the storage tank, water consumption and elevation of each node. The proposed model is applied for pressure management of a major pressure zone with an integrated storage facility in the northwest part of Tehran Metropolitan area. The results show that network 438 S. Nazif et al.leakage can be reduced more than 30% during a year when tank water level is optimized by the proposed model.

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Water Quality Based Multi-objective Optimal Design of Water Distribution Systems

Shokoohi

Tabesh

Nazif

et al. 2016

Water Resour Manage

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Development of a Hybrid Index for Drought Prediction: Case Study

2009

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Sustainability assessment of wastewater reuse alternatives using the evidential reasoning approach

Akhoundi

Nazif

2018

Journal of Cleaner Production

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Reliability-Based Flood Management in Urban Watersheds Considering Climate Change Impacts

Karamouz

Nazif

2013

J. Water Resour. Plann. Manage.

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Life cycle assessment of pipes and piping process in drinking water distribution networks to reduce environmental impact

Hajibabaei

Nazif

Sereshgi

2018

Sustainable Cities and Society

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Hydrology and Hydroclimatology

Karamouz¹,

Nazif²,

Falahi³

2012

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Uncertainty based modeling of rainfall-runoff: Combined differential evolution adaptive Metropolis (DREAM) and K-means clustering

Zahmatkesh

Karamouz

Nazif

2015

Advances in Water Resources

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Sara Nazif

Pressure Management Model for Urban Water Distribution Networks

Water Quality Based Multi-objective Optimal Design of Water Distribution Systems

Development of a Hybrid Index for Drought Prediction: Case Study

Sustainability assessment of wastewater reuse alternatives using the evidential reasoning approach

Reliability-Based Flood Management in Urban Watersheds Considering Climate Change Impacts

Life cycle assessment of pipes and piping process in drinking water distribution networks to reduce environmental impact

Hydrology and Hydroclimatology

Uncertainty based modeling of rainfall-runoff: Combined differential evolution adaptive Metropolis (DREAM) and K-means clustering

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