Optimal methodology for distribution systems reconfiguration based on OPF and solved by decomposition technique

Khodr, H.M.; Martínez-Crespo, Jorge; Vale, Zita; Ramos, Carlos

doi:10.1002/etep.353

Cited by 17 publications

(11 citation statements)

References 35 publications

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“…When we try to optimize several objectives at the same time, the search space also becomes partially ordered. To obtain the optimal solution, there will be a set of optimal trade-offs between the conflicting objectives [12,13]. However, multiobjective programming encounters difficulties in dealing with both qualitative and quantitative objectives in a decision problem.…”

Section: Multiobjective Programmingmentioning

confidence: 99%

Optimal allocation of distributed generation using a two-stage multi-objective mixed-integer-nonlinear programming

Porkar

Poure²,

Abbaspour-Tehrani-fard

et al. 2010

Euro. Trans. Electr. Power

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SUMMARYCost is one of the most essential factors that influence many decisions taken in the distribution system planning. In general, cost can be defined as everything that should be sacrificed to gain the desired results. This paper proposes a new two-stage methodology for distributed generation (DG) placement as an attractive option for distribution system planner. This method aims to minimize cost and maximize total system benefit (TSB). Optimal placement and size are obtained from total cost minimization mathematical problem which is solved in the first stage. For each DG cost characteristics and for each investment payback time, there is an optimal location and size. Then the optimal DG investment payback time results from the TSB maximization problem, which is solved in the second stage. The various DG technologies offer the opportunity of selecting the right energy solution at the right location. Five types of DG are tested to give system deciders some choices. Different system conditions are simulated to illustrate the effect of DG installation on the distribution system as well as the ability of the proposed methodology. A user-friendly software package has been developed to solve efficiently and quickly the two optimization mathematical problems. The proposed methodology has been tested on IEEE 30-bus test system.

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Section: Multiobjective Programmingmentioning

confidence: 99%

Optimal allocation of distributed generation using a two-stage multi-objective mixed-integer-nonlinear programming

Porkar

Poure²,

Abbaspour-Tehrani-fard

et al. 2010

Euro. Trans. Electr. Power

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“…"N-1" and "N-2" laws in transmission network safety and reliability evaluation and reconfiguration in distribution network operation state optimization [29] are actual examples of structure flexibility. In normal cases, there are usually some margins in the design, construction and operation of power networks.…”

Section: (4) Structure Flexibilitymentioning

confidence: 99%

“…The structure flexibility of power networks is also flexibility of system operation mode. "N-1" and "N-2" laws in transmission network safety and reliability evaluation and reconfiguration in distribution network operation state optimization [29] are actual examples of structure flexibility.…”

Section: (4) Structure Flexibilitymentioning

confidence: 99%

Flexibility evaluation and flexible comprehensive optimization in power systems

Sun

Wang

Zhang

2011

Int Trans Elec Energy Syst

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SUMMARY Smart grid puts forward new requirements in the planning, operation and management of power systems. Flexibility is one of the most important characters among the requirements. Traditional optimization analysis methods with single objective function and rigid constraints can hardly meet such requirements. This paper introduces the original concept of flexibility in industry process system analysis into power system analysis, analyzes their main differences and makes subdivision of power system flexibility into four kinds, namely property, constraint, load and structure flexibility. Rigid constraints in traditional analysis methods are transformed into flexible forms, and a power system flexibility evaluation method is proposed. Flexibility indices are defined and calculated to give intuitive measure of power system flexibility to grid dispatchers. Then, a flexible comprehensive optimization model in power system analysis is established. The result obtained is not an optimization for a single objective, but a comprehensive optimization considering system economy, safety and other objectives. Case study on IEEE 30‐bus test system shows the validity of the methodology proposed. Copyright © 2011 John Wiley & Sons, Ltd.

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“…However, both the studies 52,53 did not consider renewable DG and reconfiguration. Researchers have also used other optimization techniques such as simulated annealing, 54 artificial immune algorithm, 55,56 vaccine-enhanced artificial immune system, 57 modified plant growth simulation algorithm, 58 PSO, 59,60 GA 61-63 , runner root algorithm, 64 harmony search algorithm, 65 artificial bee colony algorithm, 66,67 hybrid Harmony search and particle artificial bee colony algorithm, 68 interval analysis, 69 stochastic MILP, 70 Ant Colony Optimization, 71 hybrid receding horizon control and scenario analysis, 72 nondominated sorting GA, 73 fuzzy mutated GA, 74 tabu search, 75 Benders decomposition approach, 76 and evolutionary programming. 77 Summary of the reviewed literature is presented in Tables 1 and 2. From the above literature survey, it is seen that most of the researchers have studied either DG installation or network reconfiguration for power loss minimization.…”

Section: Introductionmentioning

confidence: 99%

Annual energy loss reduction of distribution network through reconfiguration and renewable energy sources

Hesaroor

Das

2019

Int Trans Electr Energ Syst

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Summary Renewable energy sources are becoming popular day by day for distributed generation as technology is becoming cheaper and modular. Power loss reduction is a powerful incentive for a distribution system operator to promote distributed generation. This paper presents a method to minimize annual energy losses through the integration of nondispatchable renewable distributed generation (DG) units and network reconfiguration under varying load demand condition. The optimal location and DG power level are calculated, and then these data are used to determine DG plant size taking into account the nonavailability of renewable energy at certain times. A network reconfiguration strategy is proposed, which takes into account both the time‐varying load and the renewable energy source such that annual energy loss is minimum. The proposed methodology is applied to 33‐node and 118‐node test distribution system with different scenarios. Results show a substantial reduction in energy loss. A cost‐benefit analysis is also carried out.

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Optimal methodology for distribution systems reconfiguration based on OPF and solved by decomposition technique

Cited by 17 publications

References 35 publications

Optimal allocation of distributed generation using a two-stage multi-objective mixed-integer-nonlinear programming

Optimal allocation of distributed generation using a two-stage multi-objective mixed-integer-nonlinear programming

Flexibility evaluation and flexible comprehensive optimization in power systems

Annual energy loss reduction of distribution network through reconfiguration and renewable energy sources

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