Your search keyword '"Muljadi, Eduard"' showing total 10 results

1. Dynamic Capabilities of an Energy Storage-Embedded DFIG System.

Author

Kim, Jinho, Muljadi, Eduard, Gevorgian, Vahan, and Hoke, Anderson F.

Subjects

*UNINTERRUPTIBLE power supply, *INDEPENDENT system operators, *INDUCTION generators, *ENERGY storage, *FREQUENCY response, *POWER electronics, *SYNCHRONOUS generators

Abstract

Power electronic-based wind turbine generators (WTGs) are capable of providing inertial response to the grid by releasing kinetic energy from the turbine blade; thus, as conventional power plants are retired, the reduction of online inertia can be compensated by designing frequency controls for the WTGs. Deployment of energy storage technology for renewable generations has been increased to have the renewables centralized with a system operator as an independent power supply by making up for their nature of generation. In addition, the cost of energy storage has dropped over time and global research activities on energy storage have been funded by private industries and governments. This paper investigates the opportunity of deploying an energy storage on a doubly fed induction generator (DFIG)-based WTG to respond to the system frequency, and then explores dynamic capabilities of the energy storage-embedded DFIG to boost its contribution while the frequency response is being provided by the power system's online inertia; thus, enabling an effective delivery of ancillary services to the system. To do this, the dynamic models of DFIG and energy storage are combined and simulated under the different operating conditions of a DFIG, such as subsynchronous, synchronous, and supersynchronous operations, using the PSCAD. [ABSTRACT FROM AUTHOR]

Published

2019

2. Temporary Frequency Support of a DFIG for High Wind Power Penetration.

Author

Yang, Dejian, Kim, Jinho, Kang, Yong Cheol, Muljadi, Eduard, Zhang, Ning, Hong, Junhee, Song, Seung-Ho, and Zheng, Taiying

Subjects

WIND power, INDUCTION generators, ROTORS, KINETIC energy

Abstract

This paper proposes a temporary frequency-support scheme of a doubly fed induction generator (DFIG) that can improve the frequency nadir while ensuring rapid frequency stabilization, particularly for high wind power penetration levels (WPPLs). Upon detecting a disturbance, the power reference is increased by the incremental power and maintained for a preset period. The proposed incremental power varies with the rotor speed and WPPL. Then, to force the rotor speed to converge to a stable operating range, the reference decreases with the rotor speed. During the deceleration period, the proposed scheme releases less kinetic energy, which helps in the rapid recovery of the rotor speed. During the acceleration period, to accelerate the rotor speed recovery, the reference smoothly decreases with time and rotor speed until it reaches the maximum power point tracking curve. The test results, which are based on the IEEE 14-bus system, demonstrate that even though less kinetic energy is released, the proposed scheme can improve the frequency nadir while rapidly recovering the rotor speed under various wind conditions and penetration levels, but it is particularly effective for higher penetration levels. The scheme helps providing a promising solution to the ancillary services of a DFIG in a power system with high WPPLs. [ABSTRACT FROM PUBLISHER]

Published

2018

3. Disturbance-Adaptive Short-Term Frequency Support of a DFIG Associated With the Variable Gain Based on the ROCOF and Rotor Speed.

Author

Hwang, Min, Muljadi, Eduard, Jang, Gilsoo, and Kang, Yong Cheol

Subjects

*ELECTRIC power systems, *ELECTRIC power distribution grids, *FREQUENCIES of oscillating systems, *ELECTRICAL load shedding, *INDUCTION generators, *ROTORS

Abstract

This paper proposes a disturbance-adaptive short-term frequency support scheme of a doubly fed induction generator (DFIG) that can improve the frequency-supporting capability while ensuring stable operation. In the proposed scheme, the output of the additional control loop is determined as the product of the frequency deviation and adaptive gain, which is modified depending on the rate of change of frequency (ROCOF) and rotor speed. To achieve these objectives, the adaptive gain is set to be high during the early stage of a disturbance, when the ROCOF and rotor speed are high. Until the frequency nadir (FN), the gain decreases with the ROCOF and rotor speed. After the FN, the gain decreases only with the rotor speed. The simulation results demonstrate that the proposed scheme improves the FN and maximum ROCOF while ensuring the stable operation of a DFIG under various wind conditions irrespective of the disturbance conditions by adaptively changing the control gain with the ROCOF and rotor speed, even if the wind speed decreases and a consecutive disturbance occurs. [ABSTRACT FROM AUTHOR]

Published

2017

4. Power-Smoothing Scheme of a DFIG Using the Adaptive Gain Depending on the Rotor Speed and Frequency Deviation.

Author

Hyewon Lee, Min Hwang, Muljadi, Eduard, Sørensen, Poul, and Yong Cheol Kang

Subjects

GRID energy storage, WIND power plants, WIND speed, INDUCTION generators, MAXIMUM power point trackers

Abstract

In an electric power grid that has a high penetration level of wind, the power fluctuation of a large-scale wind power plant (WPP) caused by varying wind speeds deteriorates the system frequency regulation. This paper proposes a power-smoothing scheme of a doubly-fed induction generator (DFIG) that significantly mitigates the system frequency fluctuation while preventing over-deceleration of the rotor speed. The proposed scheme employs an additional control loop relying on the system frequency deviation that operates in combination with the maximum power point tracking control loop. To improve the power-smoothing capability while preventing over-deceleration of the rotor speed, the gain of the additional loop is modified with the rotor speed and frequency deviation. The gain is set to be high if the rotor speed and/or frequency deviation is large. The simulation results based on the IEEE 14-bus system clearly demonstrate that the proposed scheme significantly lessens the output power fluctuation of a WPP under various scenarios by modifying the gain with the rotor speed and frequency deviation, and thereby it can regulate the frequency deviation within a narrow range. [ABSTRACT FROM AUTHOR]

Published

2017

5. Stable Short-Term Frequency Support Using Adaptive Gains for a DFIG-Based Wind Power Plant.

Author

Lee, Jinsik, Jang, Gilsoo, Muljadi, Eduard, Blaabjerg, Frede, Chen, Zhe, and Cheol Kang, Yong

Subjects

POWER plants, KINETIC energy, ELECTROSTATIC induction, INDUCTION generators, WIND speed

Abstract

For the fixed-gain inertial control of wind power plants (WPPs), a large gain setting provides a large contribution to supporting system frequency control, but it may cause over-deceleration for a wind turbine generator that has a small amount of kinetic energy (KE). Further, if the wind speed decreases during inertial control, even a small gain may cause over-deceleration. This paper proposes a stable inertial control scheme using adaptive gains for a doubly fed induction generator (DFIG)-based WPP. The scheme aims to improve the frequency nadir (FN) while ensuring stable operation of all DFIGs, particularly when the wind speed decreases during inertial control. In this scheme, adaptive gains are set to be proportional to the KE stored in DFIGs, which is spatially and temporally dependent. To improve the FN, upon detecting an event, large gains are set to be proportional to the KE of DFIGs; to ensure stable operation, the gains decrease with the declining KE. The simulation results demonstrate that the scheme improves the FN while ensuring stable operation of all DFIGs in various wind and system conditions. Further, it prevents over-deceleration even when the wind speed decreases during inertial control. [ABSTRACT FROM PUBLISHER]

Published

2016

6. Dynamic Droop–Based Inertial Control of a Doubly-Fed Induction Generator.

Author

Hwang, Min, Muljadi, Eduard, Park, Jung-Wook, Sorensen, Poul, and Kang, Yong Cheol

Abstract

If a large disturbance occurs in a power grid, two auxiliary loops for the inertial control of a wind turbine generator have been used: droop loop and rate of change of frequency (ROCOF) loop. Because their gains are fixed, difficulties arise in determining them suitable for all grid and wind conditions. This paper proposes a dynamic droop-based inertial control scheme of a doubly-fed induction generator (DFIG). The scheme aims to improve the frequency nadir (FN) and ensure stable operation of a DFIG. To achieve the first goal, the scheme uses a droop loop, but it dynamically changes its gain based on the ROCOF to release a large amount of kinetic energy during the initial stage of a disturbance. To do this, a shaping function that relates the droop to the ROCOF is used. To achieve the second goal, different shaping functions, which depend on rotor speeds, are used to give a large contribution in high wind conditions and prevent over-deceleration in low wind conditions during inertial control. The performance of the proposed scheme was investigated under various wind conditions using an EMTP-RV simulator. The results indicate that the scheme improves the FN and ensures stable operation of a DFIG. [ABSTRACT FROM PUBLISHER]

Published

2016

7. Adaptive Q–V Scheme for the Voltage Control of a DFIG-Based Wind Power Plant.

Author

Kim, Jinho, Seok, Jul-Ki, Muljadi, Eduard, and Kang, Yong Cheol

Subjects

ADAPTIVE control systems, VOLTAGE control, WIND power plants, REACTIVE power, INDUCTION generators

Abstract

Wind generators within a wind power plant (WPP) will produce different amounts of active power because of the wake effect, and therefore, they have different reactive power capabilities. This paper proposes an adaptive reactive power to the voltage (Q–V) scheme for the voltage control of a doubly fed induction generator (DFIG)-based WPP. In the proposed scheme, the WPP controller uses a voltage control mode and sends a voltage error signal to each DFIG. The DFIG controller also employs a voltage control mode utilizing the adaptive Q–V characteristics depending on the reactive power capability such that a DFIG with a larger reactive power capability will inject more reactive power to ensure fast voltage recovery. Test results indicate that the proposed scheme can recover the voltage within a short time, even for a grid fault with a small short-circuit ratio, by making use of the available reactive power of a WPP and differentiating the reactive power injection in proportion to the reactive power capability. This will, therefore, help to reduce the additional reactive power and ensure fast voltage recovery. [ABSTRACT FROM AUTHOR]

Published

2016

8. Different Factors Affecting Short Circuit Behavior of a Wind Power Plant.

Author

Muljadi, Eduard, Samaan, Nader, Gevorgian, Vahan, Li, Jun, and Pasupulati, Subbaiah

Subjects

*WIND power plants, *WIND turbines, *ROTORS, *ELECTRIC circuits, *INDUCTION generators, *ELECTRIC transformers, *SHORT circuits

Abstract

A wind power plant (WPP) consists of a large number of turbines interconnected by underground cable. A pad-mounted transformer at each turbine steps up the voltage from a generating voltage (690 V) to a medium voltage (34.5 kV). All turbines in the plant are connected to the substation transformer, where the voltage is stepped up to the transmission level. An important aspect of WPP impact studies is to evaluate the short-circuit (SC) current contribution of the plant into the transmission network under different fault conditions. This task can be challenging to protection engineers due to the topology differences between different types of wind turbine generators and the conventional generating units. This paper investigates the SC behavior of a WPP for different types of faults. The impact of wind turbine types, the transformer configuration, and the reactive compensation capacitor will be investigated. The voltage response at different buses will be observed. Finally, the SC line currents will be presented along with its symmetrical components. [ABSTRACT FROM AUTHOR]

Published

2013

9. Possibility of Power Electronics-Based Control Analysis of a Self-Excited Induction Generator (SEIG) for Wind Turbine and Electrolyzer Application.

Author

Na, Woonki, Muljadi, Eduard, Han, Seungyun, Tagayi, Roland Kobla, and Kim, Jonghoon

Subjects

INDUCTION generators, WIND turbines, POWER electronics, TURBINE generators, WIND speed, ELECTROLYTIC cells, FUEL cells, ELECTRIC batteries

Abstract

A self-excited induction generator (SEIG) is very simple and robust, has a reduced unit size, is easy to implement and simple to control, and requires very little maintenance compared to other types of generators. In variable operating conditions, the SEIG requires a power electronics interface to transform from the variable frequency voltage output of the generator to a battery voltage output or the related applications. In our study, we tied the SEIG to the power electronics system comprising a diode rectifier and DC/DC converter, and then a final DC load for fuel cell applications was connected. An example of such an application is an electrolyzer where an equivalent circuit is modeled for use in this study. To accomplish the proposed system, we utilized PSCAD and MATLAB for its simulation, control, and analysis. A new system configuration considering three different wind speeds and breaker conditions is modeled and analyzed. The results show that the suggested strategies in this study would contribute to designing and analyzing a more practical power electronics interface system for a wind turbine generator with a DC load. [ABSTRACT FROM AUTHOR]

Published

2021

10. AC/DC/AC Converter Modulation Strategy with Natural Zero Sequence Rejection Using Only One Six-Switch Inverter Module

Author

Muljadi, Eduard

Published

2007