Dispatchable wind power generation planning for distribution systems

Nand K. Meena, Anil Swarnkar, Nikhil Gupta, K. R. Niazi

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Abstract

In this paper, a set of new planning strategies are proposed to optimally accommodate aggregated capacity of wind farms with special switching arrangements to make these dis-patchable. The goal is to mitigate the issues of intense renewable power penetration on distribution systems such as wind power curtailment, reverse power flow problem, high voltage problem etc. The proposed model is investigated on a standard 33-bus radial distribution system and genetic algorithm is used to solve it. The simulation results of proposed model are compared with the same obtained by conventional planning models, which shows that the proposed approach is promising.

Original languageEnglish
Title of host publication2017 7th International Conference on Power Systems, ICPS 2017
PublisherIEEE
Pages491-496
Number of pages6
ISBN (Electronic)9781538617892
DOIs
Publication statusPublished - 15 Jun 2018
Event7th International Conference on Power Systems, ICPS 2017 - Pune, India
Duration: 21 Dec 201723 Dec 2017

Conference

Conference7th International Conference on Power Systems, ICPS 2017
CountryIndia
CityPune
Period21/12/1723/12/17

Fingerprint

Wind Power
Distribution System
Wind power
Power generation
Planning
Power Flow
Penetration
Farms
Reverse
Arrangement
Genetic algorithms
Voltage
Genetic Algorithm
Model
Electric potential
Simulation

Keywords

  • Distributed generation
  • distribution systems
  • genetic algorithm
  • mixed-integer
  • wind power

Cite this

Meena, N. K., Swarnkar, A., Gupta, N., & Niazi, K. R. (2018). Dispatchable wind power generation planning for distribution systems. In 2017 7th International Conference on Power Systems, ICPS 2017 (pp. 491-496). IEEE. https://doi.org/10.1109/ICPES.2017.8387342
Meena, Nand K. ; Swarnkar, Anil ; Gupta, Nikhil ; Niazi, K. R. / Dispatchable wind power generation planning for distribution systems. 2017 7th International Conference on Power Systems, ICPS 2017. IEEE, 2018. pp. 491-496
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abstract = "In this paper, a set of new planning strategies are proposed to optimally accommodate aggregated capacity of wind farms with special switching arrangements to make these dis-patchable. The goal is to mitigate the issues of intense renewable power penetration on distribution systems such as wind power curtailment, reverse power flow problem, high voltage problem etc. The proposed model is investigated on a standard 33-bus radial distribution system and genetic algorithm is used to solve it. The simulation results of proposed model are compared with the same obtained by conventional planning models, which shows that the proposed approach is promising.",
keywords = "Distributed generation, distribution systems, genetic algorithm, mixed-integer, wind power",
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}

Meena, NK, Swarnkar, A, Gupta, N & Niazi, KR 2018, Dispatchable wind power generation planning for distribution systems. in 2017 7th International Conference on Power Systems, ICPS 2017. IEEE, pp. 491-496, 7th International Conference on Power Systems, ICPS 2017, Pune, India, 21/12/17. https://doi.org/10.1109/ICPES.2017.8387342

Dispatchable wind power generation planning for distribution systems. / Meena, Nand K.; Swarnkar, Anil; Gupta, Nikhil; Niazi, K. R.

2017 7th International Conference on Power Systems, ICPS 2017. IEEE, 2018. p. 491-496.

Research output: Chapter in Book/Report/Conference proceedingConference contribution

TY - GEN

T1 - Dispatchable wind power generation planning for distribution systems

AU - Meena, Nand K.

AU - Swarnkar, Anil

AU - Gupta, Nikhil

AU - Niazi, K. R.

PY - 2018/6/15

Y1 - 2018/6/15

N2 - In this paper, a set of new planning strategies are proposed to optimally accommodate aggregated capacity of wind farms with special switching arrangements to make these dis-patchable. The goal is to mitigate the issues of intense renewable power penetration on distribution systems such as wind power curtailment, reverse power flow problem, high voltage problem etc. The proposed model is investigated on a standard 33-bus radial distribution system and genetic algorithm is used to solve it. The simulation results of proposed model are compared with the same obtained by conventional planning models, which shows that the proposed approach is promising.

AB - In this paper, a set of new planning strategies are proposed to optimally accommodate aggregated capacity of wind farms with special switching arrangements to make these dis-patchable. The goal is to mitigate the issues of intense renewable power penetration on distribution systems such as wind power curtailment, reverse power flow problem, high voltage problem etc. The proposed model is investigated on a standard 33-bus radial distribution system and genetic algorithm is used to solve it. The simulation results of proposed model are compared with the same obtained by conventional planning models, which shows that the proposed approach is promising.

KW - Distributed generation

KW - distribution systems

KW - genetic algorithm

KW - mixed-integer

KW - wind power

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UR - https://ieeexplore.ieee.org/document/8387342

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DO - 10.1109/ICPES.2017.8387342

M3 - Conference contribution

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BT - 2017 7th International Conference on Power Systems, ICPS 2017

PB - IEEE

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Meena NK, Swarnkar A, Gupta N, Niazi KR. Dispatchable wind power generation planning for distribution systems. In 2017 7th International Conference on Power Systems, ICPS 2017. IEEE. 2018. p. 491-496 https://doi.org/10.1109/ICPES.2017.8387342