Multistage multiobjective electricity generation expansion planning for Tamil Nadu considering least cost and minimal GHG emission

Bhuvanesh, A.; Christa, S.T. Jaya; Subramanian, K.; Pandiyan, M. Karuppasamy

doi:10.1002/etep.2708

Cited by 20 publications

(11 citation statements)

References 41 publications

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“…The solar power plants with storage facilities are added with base plants as an alternate, and the resulting system is used to obtain the optimal (best) plan over 14 years (seven stages). The solution is obtained after 10 runs with three different cases for each run according to population size 15, 20, 25, and. Table shows the solution matrices of all the scenarios undertaken in this study.…”

Section: Resultsmentioning

confidence: 99%

“…A comprehensive review of optimization techniques and comparison among each other is also provided while focusing on the uncertainty and variability of RES . Bhuvanesh et al solved a multi‐objective multistage GEP problem by DE algorithm while taking into account the least green house gas (GHG) emissions . Rajesh et al combined wind power units, solar power units, and solar power with storage facility with the conventional GEP problem and solved using DE algorithm.…”

Section: Introductionmentioning

confidence: 99%

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Least‐cost generation expansion planning using whale optimization algorithm incorporating emission reduction and renewable energy sources

Nawaz

Malik

Ashraf

2019

Int Trans Electr Energ Syst

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Summary Ever‐increasing energy demand and technology development are continuously pursuing the attention of power system planners to design an optimum strategy for supplying future electrical demand. Generation expansion planning turns out to be a crucial step for an efficient energy management system in a modern power grid. In this paper, a novel whale optimization algorithm with penalty factor approach (WOA‐PFA) framework has been developed to solve a nonlinear, discrete, dynamic, highly complex, heavily constrained GEP problem. Reliability evaluation is accomplished using equivalent energy function approach. A virtual mapping procedure is utilized to add computational strength to the WOA‐PFA framework. Emission reduction is performed by utilizing total emission reduction constraint. The results are organized in four case studies starting with base power plants and adding wind, solar, and solar with storage facility in succession for the rest of case studies. Simulation results prove that the proposed WOA‐PFA shows promising results in terms of the least cost and computational time as compared with the techniques presented in the literature.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Least‐cost generation expansion planning using whale optimization algorithm incorporating emission reduction and renewable energy sources

Nawaz

Malik

Ashraf

2019

Int Trans Electr Energ Syst

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“…In this work, FOR value of the solar PV system is considered as 70%. 44 A total of 147.2 MW is allocated as reserve margin for conventional New England 39 bus system and 187.28 MW is allocated as reserve margin for a solar integrated PV system. This generation reserve is allocated to all the generators uniformly.…”

Section: Computation Of Pda-datac In Solar Integrated Deregulated Power Systemmentioning

confidence: 99%

Probabilistic day ahead dynamic available transfer capability estimation in solar integrated deregulated power system

Karuppasamypandiyan

Devaraj

et al. 2021

Int Trans Electr Energ Syst

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Available transfer capability (ATC) between the interfaces needs to be planned well in advance for a secure power transaction in a deregulated power system.Independent system operator (ISO) is responsible for determining ATC at least 24 hours before and made available for the decision makers. This work proposes an effective method to find probabilistic day ahead dynamic ATC (PDA-DATC) in a solar integrated deregulated power system. Solar photo voltaic (PV) output is stochastic which brings uncertainties in PDA-DATC calculation. Hence, it is important to predict solar PV output accurately. In this work, the solar PV output is predicted using neural network. The time-series historical data such as hourly global direct radiation, global diffusion radiation, air temperature, and sun height are taken as the input variable. The input feature selection methods such as mutual information and random forest (RF) techniques are applied to choose the input features. The impact of solar PV on PDA-DATC is analyzed. Also, the penetration of solar PV on a single location and scattered locations are studied and the results are compared for different loading conditions such as high peak, moderate, and low peak periods. The dynamic voltage stability limit namely the Hopf bifurcation limit is used as a limiting criterion for DATC computation. A new swarm intelligent-based optimization algorithm namely dragon fly algorithm (DFA) is used as an optimization algorithm for PDA-DATC

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“…Traditional household appliances are gradually transformed into intelligent appliances that can realize automatic and smart control, and uncontrollable household load are turned into productive and flexible demand response (DR) resources. Great potential for supporting and assisting the operation of power systems [1]. Therefore, together with the traditional power generation, households play an increasingly important role to improve the stability and economic operation of the power system.…”

Section: Introductionmentioning

confidence: 99%

Research on Home Energy Management Method for Demand Response Based on Chance-Constrained Programming

et al. 2020

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With the development of smart devices and information technology, it is possible for users to optimize their usage of electrical equipment through the home energy management system (HEMS). To solve the problems of daily optimal scheduling and emergency demand response (DR) in an uncertain environment, this paper provides an opportunity constraint programming model for the random variables contained in the constraint conditions. Considering the probability distribution of the random variables, a home energy management method for DR based on chance-constrained programming is proposed. Different confidence levels are set to reflect the influence mechanism of random variables on constraint conditions. An improved particle swarm optimization algorithm is used to solve the problem. Finally, the demand response characteristics in daily and emergency situations are analyzed by simulation examples, and the effectiveness of the method is verified.

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Multistage multiobjective electricity generation expansion planning for Tamil Nadu considering least cost and minimal GHG emission

Cited by 20 publications

References 41 publications

Least‐cost generation expansion planning using whale optimization algorithm incorporating emission reduction and renewable energy sources

Least‐cost generation expansion planning using whale optimization algorithm incorporating emission reduction and renewable energy sources

Probabilistic day ahead dynamic available transfer capability estimation in solar integrated deregulated power system

Research on Home Energy Management Method for Demand Response Based on Chance-Constrained Programming

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