Effective location of SMES for power fluctuation mitigation of grid connected doubly fed induction generator

“…Power quality improvement of PV and DFIG systems is presented [175], [176] with superconducting magnetic energy storage (SMES [152], [155] These methods improve dynamic voltage stabilization Further improvement is possible by systematic D-FACTS design Harmonics mitigation is achieved and power factor is improved SSFC [154] Harmonics mitigation and voltage stabilization Losses reduction and power factor improvement STATCOM [156]- [158] Point of common coupling harmonic mitigation…”

“…Voltage controller parameters can be tuned with any optimization technique Voltage deviaton reduced by 73.4% in [158] The strategy presented in [158] only considers linear load TCSC [159], [160] Machine electrical torque deviation is reduced In some cases, damping of oscillation is slower than traditional controller [159] Optimal placement of TCSC is not considered [160] SVC [161], [162] Wind and PV systems voltage profile is improved Harmonics minimization is not considered in optimization [161] Large-scale DFIG harmonic reduction is observed in [162] UPFC [163]- [165] Voltage profile and harmonics are improved UPFC can mitiage more harmonics with phase shifting capability [165] UPQC [24], [166]- [168] Voltage sag and current harmonics are mitigated Mitigation of higher order harmonics requires further research Interharmonics, noise and DC offset are improved output and utility power quality [175]. Although the power quality of DFIG wind system is improved in [176], extreme high current flows through the SMES coil which may be problematic for practical implementation of such device. To resolve this issue, improved control strategy can be proposed, or several SMES can be connected in parallel as a future research.…”

“…The parameters of battery and supercapacitor are given by experience in this study; however, the economic optimization can be employed for further power quality improvement. Power quality improvement of PV and DFIG systems is presented [163,164] with superconducting magnetic energy storage (SMES). The high temperature superconducting (HTS) coil is charged and discharged based on PV array output and utility power quality [163].…”

“…The high temperature superconducting (HTS) coil is charged and discharged based on PV array output and utility power quality [163]. Although the power quality of DFIG wind system is improved in [164], extreme high current flows through the SMES coil which may be problematic for practical implementation of such device.…”

High-Level Penetration of Renewable Energy Sources Into Grid Utility: Challenges and Solutions

“…Power quality improvement of PV and DFIG systems is presented [175], [176] with superconducting magnetic energy storage (SMES [152], [155] These methods improve dynamic voltage stabilization Further improvement is possible by systematic D-FACTS design Harmonics mitigation is achieved and power factor is improved SSFC [154] Harmonics mitigation and voltage stabilization Losses reduction and power factor improvement STATCOM [156]- [158] Point of common coupling harmonic mitigation…”

“…Voltage controller parameters can be tuned with any optimization technique Voltage deviaton reduced by 73.4% in [158] The strategy presented in [158] only considers linear load TCSC [159], [160] Machine electrical torque deviation is reduced In some cases, damping of oscillation is slower than traditional controller [159] Optimal placement of TCSC is not considered [160] SVC [161], [162] Wind and PV systems voltage profile is improved Harmonics minimization is not considered in optimization [161] Large-scale DFIG harmonic reduction is observed in [162] UPFC [163]- [165] Voltage profile and harmonics are improved UPFC can mitiage more harmonics with phase shifting capability [165] UPQC [24], [166]- [168] Voltage sag and current harmonics are mitigated Mitigation of higher order harmonics requires further research Interharmonics, noise and DC offset are improved output and utility power quality [175]. Although the power quality of DFIG wind system is improved in [176], extreme high current flows through the SMES coil which may be problematic for practical implementation of such device. To resolve this issue, improved control strategy can be proposed, or several SMES can be connected in parallel as a future research.…”

“…The parameters of battery and supercapacitor are given by experience in this study; however, the economic optimization can be employed for further power quality improvement. Power quality improvement of PV and DFIG systems is presented [163,164] with superconducting magnetic energy storage (SMES). The high temperature superconducting (HTS) coil is charged and discharged based on PV array output and utility power quality [163].…”

“…The high temperature superconducting (HTS) coil is charged and discharged based on PV array output and utility power quality [163]. Although the power quality of DFIG wind system is improved in [164], extreme high current flows through the SMES coil which may be problematic for practical implementation of such device.…”

High-Level Penetration of Renewable Energy Sources Into Grid Utility: Challenges and Solutions

“…In the process of energy conversion, the generator is the most important tool. Induction machine, permanent magnet synchronous machine and switched reluctance machine (SRM) all can be used as generators (Saeed et al , 2022; Narjes et al , 2022; Mukherjee and Rao, 2020; Namazi et al , 2020; Kokernak and Torrey, 2000; Azer et al , 2019). SRM is very suitable for generators for the reason that strong fault tolerance, high reliability, low cost and high efficiency.…”

Bipolar power converter and control of switched reluctance generator system for renewable energy storage

Integration of battery and hydrogen energy storage systems with small-scale hydropower plants in off-grid local energy communities