Optimal Operation of Distribution Feeders in Smart Grids

This paper presents a generic and comprehensive distribution optimal power flow (DOPF) model that can be used by local distribution companies (LDCs) to integrate their distribution system feeders into a Smart Grid. The proposed three-phase DOPF framework incorporates detailed modeling of distributio...

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Published in:IEEE transactions on industrial electronics (1982) 2011-10, Vol.58 (10), p.4495-4503
Main Authors: Paudyal, S., Canizares, C. A., Bhattacharya, K.
Format: Article
Language:English
Subjects:
Capacitors
Constraining
Distribution power flow
Electric potential
Equations
Feeders
Load modeling
Mathematical model
Minimization
Nonlinear programming
optimal feeder operation
Optimization
Smart Grid
Smart grids
Studies
Switches
Switching
unbalanced distribution systems
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cited_by cdi_FETCH-LOGICAL-c389t-2eb4786e7e8ea7fc99485dc28906af388b84f200fd45d6174b2b3c7cd616322c3
cites cdi_FETCH-LOGICAL-c389t-2eb4786e7e8ea7fc99485dc28906af388b84f200fd45d6174b2b3c7cd616322c3
container_end_page 4503
container_issue 10
container_start_page 4495
container_title IEEE transactions on industrial electronics (1982)
container_volume 58
creator Paudyal, S.
Canizares, C. A.
Bhattacharya, K.
description This paper presents a generic and comprehensive distribution optimal power flow (DOPF) model that can be used by local distribution companies (LDCs) to integrate their distribution system feeders into a Smart Grid. The proposed three-phase DOPF framework incorporates detailed modeling of distribution system components and considers various operating objectives. Phase specific and voltage dependent modeling of customer loads in the three-phase DOPF model allows LDC operators to determine realistic operating strategies that can improve the overall feeder efficiency. The proposed distribution system operation objective is based on the minimization of the energy drawn from the substation while seeking to minimize the number of switching operations of load tap changers and capacitors. A novel method for solving the three-phase DOPF model by transforming the mixed-integer nonlinear programming problem to a nonlinear programming problem is proposed which reduces the computational burden and facilitates its practical implementation and application. Two practical case studies, including a real distribution feeder test case, are presented to demonstrate the features of the proposed methodology. The results illustrate the benefits of the proposed DOPF in terms of reducing energy losses while limiting the number of switching operations.
doi_str_mv 10.1109/TIE.2011.2112314
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A. ; Bhattacharya, K.</creator><creatorcontrib>Paudyal, S. ; Canizares, C. A. ; Bhattacharya, K.</creatorcontrib><description>This paper presents a generic and comprehensive distribution optimal power flow (DOPF) model that can be used by local distribution companies (LDCs) to integrate their distribution system feeders into a Smart Grid. The proposed three-phase DOPF framework incorporates detailed modeling of distribution system components and considers various operating objectives. Phase specific and voltage dependent modeling of customer loads in the three-phase DOPF model allows LDC operators to determine realistic operating strategies that can improve the overall feeder efficiency. The proposed distribution system operation objective is based on the minimization of the energy drawn from the substation while seeking to minimize the number of switching operations of load tap changers and capacitors. A novel method for solving the three-phase DOPF model by transforming the mixed-integer nonlinear programming problem to a nonlinear programming problem is proposed which reduces the computational burden and facilitates its practical implementation and application. Two practical case studies, including a real distribution feeder test case, are presented to demonstrate the features of the proposed methodology. 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The proposed distribution system operation objective is based on the minimization of the energy drawn from the substation while seeking to minimize the number of switching operations of load tap changers and capacitors. A novel method for solving the three-phase DOPF model by transforming the mixed-integer nonlinear programming problem to a nonlinear programming problem is proposed which reduces the computational burden and facilitates its practical implementation and application. Two practical case studies, including a real distribution feeder test case, are presented to demonstrate the features of the proposed methodology. 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Phase specific and voltage dependent modeling of customer loads in the three-phase DOPF model allows LDC operators to determine realistic operating strategies that can improve the overall feeder efficiency. The proposed distribution system operation objective is based on the minimization of the energy drawn from the substation while seeking to minimize the number of switching operations of load tap changers and capacitors. A novel method for solving the three-phase DOPF model by transforming the mixed-integer nonlinear programming problem to a nonlinear programming problem is proposed which reduces the computational burden and facilitates its practical implementation and application. Two practical case studies, including a real distribution feeder test case, are presented to demonstrate the features of the proposed methodology. 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source IEEE Electronic Library (IEL) Journals
subjects Capacitors
Constraining
Distribution power flow
Electric potential
Equations
Feeders
Load modeling
Mathematical model
Minimization
Nonlinear programming
optimal feeder operation
Optimization
Smart Grid
Smart grids
Studies
Switches
Switching
unbalanced distribution systems
title Optimal Operation of Distribution Feeders in Smart Grids
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