Review on reliability improvement and power loss reduction in distribution system via network reconfiguration

Sultana, Beenish; Mustafa, Mohd Wazir; Sultana, Umbrin; Bhatti, Abdul Rauf

doi:10.1016/j.rser.2016.08.011

Cited by 149 publications

(53 citation statements)

References 96 publications

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“…In the proposed study, system performance indices SAIFI, SAIDI, and CAIDI will be calculated. Based on Equations and , other distribution reliability indices such as ASAI, EENS and AENS could also be easily calculated The system performance indices SAIFI, SAIDI, and CAIDI are determined on levels

scriptℓ = 0

and

scriptℓ > 0

.…”

Section: Methodology Of Reliability Assessment Using Mlmc Methodsmentioning

confidence: 99%

Improving distribution system reliability calculation efficiency using multilevel Monte Carlo method

Huda

Živanović

2017

Int. Trans. Electr. Energ. Syst.

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Power distribution system reliability is generally evaluated by sequential Monte Carlo simulation (MCS). To obtain a high accuracy, we found that sequential MCS technique needs long execution time. In this paper, we show that reliability indices could be evaluated using a novel sequential multilevel Monte Carlo technique that improves the computational efficiency of MCS. The key idea behind the multilevel Monte Carlo method is to use computationally cheaper low-accuracy solutions of coarse grids as control variates for high-accuracy solutions of fine grids. Therefore, the proposed method can construct multilevel estimators of reliability indices with lower variance. Reliability indices are modelled based on stochastic differential equations and exponential probability distributions. The Milstein path discretisation is used to approximate the numerical solution of stochastic differential equations. Case studies are performed on a small distribution system. Numerical results are presented to demonstrate the computational cost-effectiveness of the proposed method in comparison with the sequential MCS.

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scriptℓ = 0

and

scriptℓ > 0

.…”

Section: Methodology Of Reliability Assessment Using Mlmc Methodsmentioning

confidence: 99%

Improving distribution system reliability calculation efficiency using multilevel Monte Carlo method

Huda

Živanović

2017

Int. Trans. Electr. Energ. Syst.

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“…Distribution systems, more often than not, are operated in radial configuration, although structured in mesh topology . Radial operation of distribution systems boosts efficient coordination of protection schemes, reduces short circuit current fault level, makes trouble‐shooting of faults easier and permits lengthy extension of distribution feeder lines . Voltage at the distribution end of power systems is comparatively lower compared to the magnitude of distribution current which is substantially higher .…”

Section: Introductionmentioning

confidence: 99%

“…Research findings had shown that the effects of the foregoing scenarios had translated to severe real power losses of about 13% with respect to total generated power and, by extension, lowered its fidelity in meeting up with the basic requirements of ideal distribution systems, which are: appropriate voltage magnitude, sustainable reliability, and adequate availability of power subject to demand . Works of several other researchers have also established that 80% interruption to stable availability of power is as a result of unhealthy disturbances at distribution sections of power systems, while other scholars tagged distribution systems as the prime engineer of outages in power systems . Suffice to point out that consumers at the farther end of distribution substations are known, over time, to experience severe voltage magnitude violations on daily basis and as a consequence, many of the sensitive electrical equipment/loads connected are unavoidably mired from executing their statutory function satisfactorily .…”

Section: Introductionmentioning

confidence: 99%

“…One of the relatively less expensive approaches that have been employed over time is the use of shunt capacitors among other approaches . Shunt capacitors are local reactive power compensators capable of improving substantially system aggregate performances such as power factor improvement, sustenance of voltage levels within the statutory limits and releasing of feeder capacity not only to carry additional loads but also to shoulder supplementary loads along the route of other feeders for the same amount of maximum permissible voltage drop and energy loss . Shunt capacitors compensate the lagging reactive power by diminishing both the line currents and reactive power demand even up to generation equipment and as a consequence, line losses and loadings become reduced in substation transformers, transmission lines and distribution lines …”

Section: Introductionmentioning

confidence: 99%

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A two‐stage approach to shunt capacitor‐based optimal reactive power compensation using loss sensitivity factor and cuckoo search algorithm

et al. 2020

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Reactive power compensation on radial distribution systems is a challenging issue. Electric power distribution systems are being bedeviled by high active power loss and severe voltage violation especially on the buses that are far from distribution substations. This article presents a two-stage approach for sizing shunt capacitors and identifying the locations where their placement would be most beneficial within radial distribution systems. A multiobjective function capturing real power loss minimization and bus voltage profile enhancement was formulated and weighted approach was engaged to transform the function into single objective one. While backward forward sweep approach was used for the load flow analysis, loss sensitivity factor was employed to predetermine suitable sites for capacitor installation, with the optimal sites and sizes determined using cuckoo search algorithm. This approach was implemented on IEEE 15-bus and Yale 17-bus/11 kV feeder.Results obtained using the method was thereafter compared with those obtained through other methods as obtained from literature and the comparison shows that cuckoo search algorithm outsmarts others. Significant reduction in real power loss, coupled with appreciable enhancement in voltage profile, is achieved on the Yale 17-bus/11 kV feeder. The approach is therefore viable for addressing reactive power compensation problems confronting practical radial distribution systems. K E Y W O R D Sbackward forward sweep, cuckoo search algorithm, loss sensitivity factor, radial distribution system, shunt capacitor

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“…A multi‐objective network reconfiguration in parallel with renewable DGs sitting and sizing for minimizing active power loss and annual operation costs has been conducted in Hamidal et al Another similar multi‐objective method for optimal network reconfiguration as well as reactive power dispatches of distributed generations has been proposed to improve the network performances by using nondominated sorting particle swarm optimization . The methods, which have been utilized to reconfigure the network for enhancing reliability and reducing losses, have been compared in Sultana et al Distribution network reconfiguration based on maximizing reliability by using the binary particle swarm optimization (BPSO) search algorithm in Amanulla et al and mixed‐integer second‐order conic programming (MISOCP) in López et al have been accomplished.…”

Section: Introductionmentioning

confidence: 99%

Modified branch exchange reconfiguration of active distributed network for simultaneous loss reduction and power quality improvement

Dejamkhooy

Khaneghah

Shayeghi

2019

Int Trans Electr Energ Syst

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Summary Traditionally active power loss and power quality issues are major concerns in distribution network management. Nowadays, these concerns become more important by integrating distributed energy resources (DERs) in the networks. Network reconfiguration has been adopted as an effective remedy. In this paper, loss reduction and improvement of power quality indices such as total harmonic distortion (THD) and voltage sag are modeled as a multi‐objective problem. The function is weighted sum of terms, which are dealt with each objective. To solve the problem, branch exchange method for the network reconfiguration is modified. In the proposed algorithm, branch exchange operation iterates sequentially. Then, the yielded solution is compared with the best one that has been saved in the memory unit. Because memory is utilized in the method, it is called retentive branch exchange. Application of the proposed method is validated by planning and simulating six scenarios for an unbalanced radial 25‐bus network. For different operation conditions and power quality disturbances, simulation results show high ability and effectiveness of the proposed method.

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Review on reliability improvement and power loss reduction in distribution system via network reconfiguration

Cited by 149 publications

References 96 publications

Improving distribution system reliability calculation efficiency using multilevel Monte Carlo method

Improving distribution system reliability calculation efficiency using multilevel Monte Carlo method

A two‐stage approach to shunt capacitor‐based optimal reactive power compensation using loss sensitivity factor and cuckoo search algorithm

Modified branch exchange reconfiguration of active distributed network for simultaneous loss reduction and power quality improvement

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