Integrated DFIG–SCIG‐based wind energy conversion system equipped with improved power generation capability

Parida, Adikanda; Chatterjee, Debashis

doi:10.1049/iet-gtd.2016.1246

Cited by 14 publications

(7 citation statements)

References 32 publications

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“…Hence, the DFIG is one of the most significant types of generators being installed in wind turbines. In DFIG, both stator and rotor are connected to the main power grid directly and by power electronic converters, respectively [24][25][26][27][28]. As it can be seen in Figure 1, the typical circuit of a doubly fed induction generator DFIG is specified, by taking into consideration the several important parts including maximum power point tracking (MPPT), rotor and grid side controllers and power electronic converters, and pulse wide modulation PWM.…”

Section: Active and Reactive Power Control In The Ocean Wind Energy Smentioning

confidence: 99%

Ocean Wind Energy Technologies in Modern Electric Networks: Opportunity and Challenges

Gandoman¹,

Ahmadi²,

Aleem³

et al. 2020

Advances in Modelling and Control of Wind and Hydrogenerators

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Wind energy is one of the most important sources of energy in the world. In recent decades, wind as one of the massive marine energy resources in the ocean to produce electricity has been used. This chapter introduces a comprehensive overview of the efficient ocean wind energy technologies, and the global wind energies in both offshore and onshore sides are discussed. Also, the classification of global ocean wind energy resources is presented. Moreover, different components of a wind farm offshore as well as the technologies used in them are investigated. Possible layouts regarding the foundation of an offshore wind turbine, floating offshore, as well as the operation of wind farms in the shallow and deep location of the ocean are studied. Finally, the offshore wind power plant challenges are described.

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Section: Active and Reactive Power Control In The Ocean Wind Energy Smentioning

confidence: 99%

Ocean Wind Energy Technologies in Modern Electric Networks: Opportunity and Challenges

Gandoman¹,

Ahmadi²,

Aleem³

et al. 2020

Advances in Modelling and Control of Wind and Hydrogenerators

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show abstract

“…[24][25][26][27] The stator and the rotor of the DFIG are coupled to the common DC link to minimize the complexity in dynamics of power control by isolating DFIG stator frequency. DFIG has the capability of voltage stability over wide speed range based on variable turbine input.…”

Section: Proposed Hybrid Generation Schemementioning

confidence: 99%

“…DFIG has the capability of voltage stability over wide speed range based on variable turbine input. [24][25][26][27] The stator and the rotor of the DFIG are coupled to the common DC link to minimize the complexity in dynamics of power control by isolating DFIG stator frequency. As shown in Figure 3, the total load has been planned to be connected to the DC link, which may be extended to serve as the DC microgrid for multiarea power supply through a multigenerator system including the electric vehicle charging load.…”

Section: Proposed Hybrid Generation Schemementioning

confidence: 99%

Remote area power supply through suitable solar PV augmented micro‐hydro generation: A case study

Parida

Chatterjee

2019

Int Trans Electr Energ Syst

Self Cite

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Summary Electrification in remote villages using locally available hybrid renewable energy sources is a viable option to eradicate energy poverty. At the same time, energy supply to the unprivileged population at the affordable cost is a major issue. Moreover, appropriate technology is the key factor for the sustainable operation of small‐scale generation system in remote places. Therefore, in this paper, a simple controller‐based standalone solar photovoltaic (PV) augmented micro‐hydro generation system suitable for remote area has been proposed. Because of its robustness for wide speed range applications, doubly fed induction generator (DFIG) has been used for micro‐hydro power generation in the proposed scheme. The developed controller effectively stabilizes the load voltage with load, micro‐hydro generation, and solar PV generation variations. In order to provide cost‐effective renewable power supply to the rural population, a generation capacity trade‐off criterion has been developed considering solar PV and micro‐hydro generations as the two operators. In the proposed trade‐off process, cost analysis has been performed considering the salvage dumping cost (SDC) for solar PV. The proposed hybrid generation scheme has been simulated through HOMER Pro‐3.2 for cost‐benefit analysis. Also, a prototype hardware set‐up for the proposed scheme has been developed and tested successfully. In this paper, Section 1 describes literature review; Section 2 discusses power generation strategy; Section 3 discusses energy cost analysis; and Section 4 describes experimental results.

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“…In [8], power quality in the electric grid and to integrate wind electricity production utilizing Stockwell's transform (ST) throughout different operating cases. Likewise, in the earlier phase, standalone DFIG off-grid systems have been suggested as outlined [9]- [12] for isolated area electrification. It was found that generator performance and power supply intermission are the main challenges in these suggested methods.…”

Section: Introductionmentioning

confidence: 99%

Design and control of grid-connected solar-wind integrated conversion system with DFIG supplying three-phase four-wire loads

Shivashankar

Keshavamurthy

2021

IJPEDS

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<p>This paper describes the architecture and control of an autonomous hybrid solar-wind system (AHSWS) powered distributed generation system supplying to a 3ϕ-4 wire system. It includes a nonlinear controlling technique for maximum power point tracking (MPPT) used in doubly fed induction generator dependent wind energy translation scheme and solar photovoltaic system (SPVS). In the hybrid model, the DC/DC converter output from the PV system is explicitly coupled with the DC-link of DFIG's back-to-back converter. An arithmetical model of the device is developed, derived using a suitable d-q reference frame. The grid-voltage-oriented vector regulation is required to manage the GSC to keep the steady-state voltage of the DC bus and to adjust reactive power on the grid side. Also, the stator-voltageoriented control scheme offers a stable function of DFIG to regulate the RSC on the stator edge for reactive and active power management in this approach. DC/DC converter is being used to maintain the maximum power from SPVS. A Perturb & Observe method is used for tracing maximum power in an SPVS. The simulation designs of 4.0kW DFIG and 4.5kW solar array simulator are built-in SIMPOWER software kit of MATLAB, it is shown to achieve optimum efficiency under various mechanical and electrical circumstances. It can produce rated frequency and voltage in both scenarios.</p>

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Integrated DFIG–SCIG‐based wind energy conversion system equipped with improved power generation capability

Cited by 14 publications

References 32 publications

Ocean Wind Energy Technologies in Modern Electric Networks: Opportunity and Challenges

Ocean Wind Energy Technologies in Modern Electric Networks: Opportunity and Challenges

Remote area power supply through suitable solar PV augmented micro‐hydro generation: A case study

Design and control of grid-connected solar-wind integrated conversion system with DFIG supplying three-phase four-wire loads

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