Optimal Pressure Management in Water Distribution Systems Using an Accurate Pressure Reducing Valve Model Based Complementarity Constraints

Dai, Pham Duc

doi:10.3390/w13060825

Cited by 15 publications

(19 citation statements)

References 44 publications

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“…This means that the distribution system could experiences bursts and leakages in the area with high pressure ( Awe et al., 2020 ). This high water losses can cause service interruptions, energy losses, and pollutant ingress ( Dai, 2021 ). Here, pressure reducing valves and zoning are very important to minimize such problems.…”

Section: Resultsmentioning

confidence: 99%

“…There are two types of water losses in water distribution systems (WDSs): real and apparent losses. Leaks at network fittings, pipe joints, breaks and/or bursts in pipes are the main causes of real losses, whereas apparent losses are caused by inaccurate meters and/or unauthorized consumption ( Dai, 2021 ; Lambert A.O., 2002 ; Puust et al., 2010 ). Due to low or even negative pressure situations, high water losses can cause service interruptions, energy losses, and pollutant ingress ( AL-Washali et al., 2020 ; Dai, 2021 ; Kouchi et al., 2017 ).…”

Section: Introductionmentioning

confidence: 99%

“…Leaks at network fittings, pipe joints, breaks and/or bursts in pipes are the main causes of real losses, whereas apparent losses are caused by inaccurate meters and/or unauthorized consumption ( Dai, 2021 ; Lambert A.O., 2002 ; Puust et al., 2010 ). Due to low or even negative pressure situations, high water losses can cause service interruptions, energy losses, and pollutant ingress ( AL-Washali et al., 2020 ; Dai, 2021 ; Kouchi et al., 2017 ). With increased retention time in the water distribution system, water quality will decline, resulting in problems such as disinfection by-product generation, disinfectant decay, corrosion, taste, and odor ( Cheng et al., 2015 ).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Modeling and optimization of pressure and water age for evaluation of urban water distribution systems performance

Desta

Fufa

Debela

2022

Heliyon

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Modeling and optimization of pressure and water age for evaluation of urban water distribution systems performance

Desta

Fufa

Debela

2022

Heliyon

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“…Nonlinear models for the control of pipeline networks are presented in Kaltenbacher et al (2017Kaltenbacher et al ( , 2018; De Persis and Kallesoe (2011). Control strategies for regulating hydraulic networks using pressure reducing valves are presented in Prescott and Ulanicki (2008); Bermúdez et al (2021a); Dai (2021); Galuppini et al (2020); Bermúdez et al (2021b). Flow control of fluid in pipelines using torsional actuator placed on a motor pump is presented in Razvarz et al (2020).…”

Section: Introductionmentioning

confidence: 99%

Modeling and Control of Pipeline Networks Supplied by Automated Irrigation Channels

Mavkov

Strecker

Zecchin

et al. 2022

J. Irrig. Drain Eng.

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A model-based approach to control system design is developed for regulating the discharge flows at the outlets of a pipeline network that is supplied by an irrigation channel. The open channel is also controlled automatically to regulate the supply-point water level. The hydraulic pressure at the source of the network is therefore dynamic when flow load varies. Regulation of the piped discharge flows is achieved by adjusting outlet control valves on the basis of the specified flow demand and sensor measurements. A blend of feedforward and feedback control is proposed. The steady-state behaviour of a non-linear distributed-parameter model of the network is used to determine the feedforward control action. The feedback control action is used to compensate for modelling error. The design of the feedback controller is based on a frequencydomain transfer function model of the system dynamics, and classical loop-shaping ideas. This model is obtained via the admittance matrix of linearized network equations. The synthesis of both centralized and decentralized feedback controller configurations is considered. Simulations that involve a non-linear distributed-parameter model of the network dynamics are used to illustrate controller performance.

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“…However, the type of the PRVs and the control strategy to be used may need to be carefully selected, given that the laboratory tests in [15] showed some pressure oscillation when using the piston-actuated PRVs. Furthermore, it was shown in [16] that model formulation of the said PRVs bears relevance in the solution of the nonlinear programming (NLP) formulated for pressure control.…”

Section: Introductionmentioning

confidence: 99%

Appraising the Impact of Pressure Control on Leakage Flow in Water Distribution Networks

Mosetlhe

Hamam

2021

Water

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Water losses in Water Distribution Networks (WDNs) are inevitable. This is due to joints interconnections, ageing infrastructure and excessive pressure at lower demand. Pressure control has been showing promising results as a means of minimising water loss. Furthermore, it has been shown that pressure information at critical nodes is often adequate to ensure effective control in the system. In this work, a greedy algorithm for the identification of critical nodes is presented. An emulator for the WDN solution is put forward and used to simulate the dynamics of the WDN. A model-free control scheme based on reinforcement learning is used to interact with the proposed emulator to determine optimal pressure reducing valve settings based on the pressure information from the critical node. Results show that flows through the pipes and nodal pressure heads can be reduced using this scheme. The reduction in flows and nodal pressure leads to reduced leakage flows from the system. Moreover, the control scheme used in this work relies on the current operation of the system, unlike traditional machine learning methods that require prior knowledge about the system.

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Optimal Pressure Management in Water Distribution Systems Using an Accurate Pressure Reducing Valve Model Based Complementarity Constraints

Cited by 15 publications

References 44 publications

Modeling and optimization of pressure and water age for evaluation of urban water distribution systems performance

Modeling and optimization of pressure and water age for evaluation of urban water distribution systems performance

Modeling and Control of Pipeline Networks Supplied by Automated Irrigation Channels

Appraising the Impact of Pressure Control on Leakage Flow in Water Distribution Networks

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