Distributed Generation Planning: A New Approach Based on Goal Programming

Vinothkumar, K; Selvan, M. P.

doi:10.1080/15325008.2011.647238

Cited by 53 publications

(21 citation statements)

References 27 publications

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“…Authors presented optimal DG allocation and sizing in distribution systems with an objective of loss minimization, guarantee acceptable reliability level and voltage profile using GA [12]. A goal programming technique is developed in [13] for formulation and evaluation of a multi objective function, for optimal planning of DG units in the distribution system. Multiple DG placement using improved analytical method and loss sensitivity factor (LSF) method is presented in [14].…”

Section: Introductionmentioning

confidence: 99%

Optimal placement of DG in radial distribution systems based on new voltage stability index under load growth

Murty

Kumar

2015

International Journal of Electrical Power & Energy Systems

244

132

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Section: Introductionmentioning

confidence: 99%

Optimal placement of DG in radial distribution systems based on new voltage stability index under load growth

Murty

Kumar

2015

International Journal of Electrical Power & Energy Systems

244

132

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“…The Chu-Beasley GA solves a nonlinear bi-level ODGP problem that maximizes the profits of DGs' owner subject to the minimization of payments procured by the DNO (López et al, 2012). Goal programming transforms a multi-objective ODGP into a single objective one which is solved by GA (Vinothkumar and Selvan, 2012). GA and decision theory are applied to solve an ODGP problem under uncertainty including power quality issues (Caprinelli et al, 2003).…”

Section: Introductionmentioning

confidence: 99%

GA-based multi-objective optimization for distributed generations planning with DLMs in distribution power systems

Singh¹,

Mukherjee

Tiwari

2017

Journal of Electrical Systems and Information Technology

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Please cite this article in press as: Singh, B., et al., GA-based multi-objective optimization for distributed generations planning with DLMs in distribution power systems. J. Electr. Syst. Inform. Technol. (2016), http://dx. AbstractIn the present scenario of all over world, the planning of distributed generations (DGs) in distribution power systems are very important issues from power system performances viewpoints. The broad categories of different types of DGs on the basis of their power delivering characteristics are considered T 1 , T 2 , T 3 and T 4 with different load models (DLMs) for the analysis in this paper. This paper presents the impact assessment of optimally placed different types of DGs (such as T 1 , T 2 , T 3 and T 4 ) with DLMs by employing genetic algorithm (GA) in the distribution power systems (DPSs) form total minimum real power loss of the system viewpoint. Different DPS performance parameters such as minimization of real power loss, minimization of reactive power loss, improvement of voltage profile, reduction of the short circuit current or MVA line capacity and reduction of the environmental green house gases like carbon dioxide (CO 2 ), sulphur dioxide (SO 2 ), nitrogen oxide (NO x ) and particulate matters in emergency e.g. under fault, sudden change in field excitation of alternators or load increase in the distribution power system are considered. The contribution of the present work is to investigate the comparisons of different DGs with DLMs by excercizing GA in the distribution systems form minimum total real power loss of the system viewpoint. The effectiveness of the proposed methodology is tested on IEEE-37 bus distribution test system. The different types of DGs (such as T 1 , T 2 , T 3 and T 4 ) with DLMs have shown different behaviours for power system performance indices such as PLI, QLI, VDI, SCCI and EIRI viewpoints. The sequence of overall power system performance indices such as PLI, QLI, VDI, SCCI and EIRI are as follows: T 2 > T 1 > T 4 > T 3 . This paper presents that the overall performance of T 2 type DG is better as compared to T 1 , T 3 and T 4 types DGs in the distribution system form minimum real power loss of the system viewpoint.Please cite this article in press as: Singh, B., et al., GA-based multi-objective optimization for distributed generations planning with DLMs in distribution power systems. J. Electr. Syst. Inform. Technol. (2016), http://dx.

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“…The ε-constrained method [21,22]; MCS [23]; goal programming [26,32]; fuzzy, WSM [29]; MCS, AHP [30]; PSO [31] and multi-criteria stochastic programming model (MSPM) [34]; VPQ (B): GA based fuzzy multi-objective method [54,60].…”

Section: Hybrid Methodsmentioning

confidence: 99%

Multi-Objective Planning Techniques in Distribution Networks: A Composite Review

2017

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Distribution networks (DNWs) are facing numerous challenges, notably growing load demands, environmental concerns, operational constraints and expansion limitations with the current infrastructure. These challenges serve as a motivation factor for various distribution network planning (DP) strategies, such as timely addressing load growth aiming at prominent objectives such as reliability, power quality, economic viability, system stability and deferring costly reinforcements. The continuous transformation of passive to active distribution networks (ADN) needs to consider choices, primarily distributed generation (DG), network topology change, installation of new protection devices and key enablers as planning options in addition to traditional grid reinforcements. Since modern DP (MDP) in deregulated market environments includes multiple stakeholders, primarily owners, regulators, operators and consumers, one solution fit for all planning scenarios may not satisfy all these stakeholders. Hence, this paper presents a review of several planning techniques (PTs) based on mult-objective optimizations (MOOs) in DNWs, aiming at better trade-off solutions among conflicting objectives and satisfying multiple stakeholders. The PTs in the paper spread across four distinct planning classifications including DG units as an alternative to costly reinforcements, capacitors and power electronic devices for ensuring power quality aspects, grid reinforcements, expansions, and upgrades as a separate category and network topology alteration and reconfiguration as a viable planning option. Several research works associated with multi-objective planning techniques (MOPT) have been reviewed with relevant models, methods and achieved objectives, abiding with system constraints. The paper also provides a composite review of current research accounts and interdependence of associated components in the respective classifications. The potential future planning areas, aiming at the multi-objective-based frameworks, are also presented in this paper.Keywords: active distribution network (ADN); distributed generation (DG); distributed energy resources (DERs); distribution network planning (DP); multi-objective optimization (MOO); multi-criteria decision analysis (MCDA); distributed generation placement (DGP); volt-ampere reactive power (VAR) compensation and power quality (VPQ); component reinforcement and up gradation (CRU); network (distribution) topology change and reconfiguration (NTR); planning techniques (PT); multiple objective planning (MOP); multi-objective planning techniques (MOPTs); future distribution networks (FDNs)

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Distributed Generation Planning: A New Approach Based on Goal Programming

Cited by 53 publications

References 27 publications

Optimal placement of DG in radial distribution systems based on new voltage stability index under load growth

Optimal placement of DG in radial distribution systems based on new voltage stability index under load growth

GA-based multi-objective optimization for distributed generations planning with DLMs in distribution power systems

Multi-Objective Planning Techniques in Distribution Networks: A Composite Review

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