Design of a Control Scheme for Distribution Static Synchronous Compensators with Power-Quality Improvement Capability

Roncero‐Sánchez, Pedro; Acha, E.

doi:10.3390/en7042476

Cited by 15 publications

(11 citation statements)

References 34 publications

(51 reference statements)

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“…which can be approximated by the instantaneous active power p if the losses in the connection filter are disregarded, i.e., p cDC ≈ v d i st d [15].…”

Section: Dstatcom Model In a Synchronous Reference Framementioning

confidence: 99%

Harmonic and imbalance voltage mitigation in smart grids: A DSTATCOM based solution

Roncero‐Sánchez

Acha

2015

IEEE EUROCON 2015 - International Conference on Computer as a Tool (EUROCON)

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This paper presents a control system for a DSTAT-COM with which to compensate the voltage sags, unbalanced voltages and voltage harmonics caused by unbalanced loads and nonlinear loads, which can be use to enhance the power quality in smart grids. The compensation of the voltage sags is carried out by injecting reactive power, while the voltage harmonics and voltage imbalances are ameliorated by canceling out the harmonics and the imbalances of the grid current. The control scheme is designed in the synchronous reference frame with a nested control structure which contains PI controllers and resonant regulators. These regulators are tuned at the harmonic frequencies to be eliminated and can be implemented to incorporate an update of those frequencies. Simulation results show the resultant time response of the voltage at the point of common coupling and the grid current.

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“…which can be approximated by the instantaneous active power p if the losses in the connection filter are disregarded, i.e., p cDC ≈ v d i st d [15].…”

Section: Dstatcom Model In a Synchronous Reference Framementioning

confidence: 99%

Harmonic and imbalance voltage mitigation in smart grids: A DSTATCOM based solution

Roncero‐Sánchez

Acha

2015

IEEE EUROCON 2015 - International Conference on Computer as a Tool (EUROCON)

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“…Figure 1 shows the ENTSO-E LVRT requirement for grid-connection, where the wind farms are expected to stay connected even when the grid voltage drops down to 0. In summary, the harmonic components, the voltage fluctuation and the LVRT capability are the crucial issues and should be carefully addressed to improve the power quality and increase the operating efficiency of wind farms [12][13][14][15].…”

Section: Introductionmentioning

confidence: 99%

Power Quality Improvement and LVRT Capability Enhancement of Wind Farms by Means of an Inductive Filtering Method

Peng

et al. 2016

Energies

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Unlike the traditional method for power quality improvement and low-voltage ride through (LVRT) capability enhancement of wind farms, this paper proposes a new wind power integrated system by means of an inductive filtering method, especially if it contains a grid-connected transformer, a static synchronous compensator (STATCOM) and fully-tuned (FT) branches. First, the main circuit topology of the new wind power integrated system is presented. Then, the mathematical model is established to reveal the mechanism of harmonic suppression and the reactive compensation of the proposed wind power integrated system, and then the realization conditions of the inductive filtering method is obtained. Further, the control strategy of STATCOM is introduced. Based on the measured data for a real wind farm, the simulation studies are carried out to illustrate the performance of the proposed new wind power integrated system. The results indicate that the new system can not only enhance the LVRT capability of wind farms, but also prevent harmonic components flowing into the primary (grid) winding of the grid-connected transformer. Moreover, since the new method can compensate for reactive power in a wind farm, the power factor at the grid side can be improved effectively.

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“…The use of the SRF allows the q component of the grid voltage to be zero and the sinusoidal magnitudes to become DC variables [34]. The following state-variable model of the grid-connected converter is obtained when the SRF is employed [35]: Although the state-variable model (Equation (9)) is coupled, a decoupled equivalent system can be obtained for control purposes, as explained in [34]. Furthermore, if an invariant-power Park's transformation is chosen, the active power, p g , and the reactive power, q g , injected into the grid can be calculated in the SRF as follows:…”

Section: Model Of the Grid-connected Convertermentioning

confidence: 99%

“…This control structure is designed by taking into account the state-space model (Equation (9)), which is coupled, as mentioned in Section 2.4. In order to tackle this problem, the following decoupled model can be achieved after some calculations (see reference [34] for more details):…”

Section: Control System Of the Voltage Of The Dc-link And The Grid-comentioning

confidence: 99%

Control Scheme of a Concentration Photovoltaic Plant with a Hybrid Energy Storage System Connected to the Grid

Roncero‐Sánchez

Torres²,

Vázquez

2018

Energies

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Abstract:In the last few decades, renewable energy sources (RESs) have been integrated into the electrical grid in order to curb the deficiency of energy owing to, among other factors, the depletion of fossil fuels and the increasing awareness of climate change. However, the stochastic nature of these sources, along with changes in levels of energy consumption, signifies that attention now needs to be paid for energy storage systems (ESSs). One of the most promising RESs is concentration photovoltaic (CPV) energy, owing to the high efficiency obtained and its sustainability regarding environmental issues. However, as CPV systems work only with direct solar radiation, they require ESSs in order to smooth the variations in the energy generated. This paper deals with the integration into the grid of a CPV plant that employs a hybrid ESS (HESS) based on ultracapacitors and batteries. The HESS allows the complete system to inject a constant active power level into the grid and thus flatten the profile of the energy generated. This goal is achieved by using a power electronic topology based on various DC-DC converters and a DC-AC converter, both of which share the same DC link. The control system is tailored in order to decouple the active-power and the reactive-power injections. Simulation results obtained using PSCAD/EMTDC (Power System Computer Aided Design/Electromagnetic Transient Direct Current) show the resulting performance of a 200 kW CPV plant with a hybrid ESS.

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Design of a Control Scheme for Distribution Static Synchronous Compensators with Power-Quality Improvement Capability

Cited by 15 publications

References 34 publications

Harmonic and imbalance voltage mitigation in smart grids: A DSTATCOM based solution

Harmonic and imbalance voltage mitigation in smart grids: A DSTATCOM based solution

Power Quality Improvement and LVRT Capability Enhancement of Wind Farms by Means of an Inductive Filtering Method

Control Scheme of a Concentration Photovoltaic Plant with a Hybrid Energy Storage System Connected to the Grid

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