Modeling and Mitigation for High Frequency Switching Transients Due to Energization in Offshore Wind Farms

Xin, Yanli; Liu, Bo; Tang, Wenhu

doi:10.3390/en9121044

Cited by 18 publications

(12 citation statements)

References 22 publications

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“…The test results show that severe HF SOVs are induced on T G , when VCB G is switched off while WTG is connected. Thus, to reveal the mechanism for the occurrence of SOV in this scenario, and investigate the impact of system configurations on SOV, such as the length of submarine cable [13], the topology of the collector system [14], the setting of reactive power compensation capacity [15], and the arcing characteristic of VCB [16], a HF simulation model for an OWF is built in PSCAD/EMTDC. In the developed model, the voltage source is replaced by an ideal power grid with an infinite capacity.…”

Section: Accurate Modeling Of Offshore Wind Farmsmentioning

confidence: 99%

“…The parameters of the three-core submarine cable are set according to the actual geometric structure of the cable used in tests. The HF model of T G is designed with the method in [14], in which the inter-phase stray capacitance and the phase-to-ground capacitance under the HF state are considered. The solution time step in PSCAD is set 0.5 µs, and it is small enough to calculate SOVs, in which the HF component is around dozens of kilohertz.…”

Section: Accurate Modeling Of Offshore Wind Farmsmentioning

confidence: 99%

“…According to the parameters of cable (Fig. 3) and the recommended value in [14], C = C C +C T = 0.15 nF m×80 m+3 nF = 15 nF. To verify the relationship of (3), namely whether the impact of the HF current and the total phase-to-ground capacitance on the steepness of SOV is in accordance with the relationship in (3), the SOV and HF current in phase A/B during ten ignitions are calculated in Fig.…”

Section: ) Steepness Calculation Of Sov Induced By Vccmentioning

confidence: 99%

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Impact Factor Identification for Switching Overvoltage in an Offshore Wind Farm by Analyzing Multiple Ignition Transients

et al. 2019

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This paper investigates the impact factors of switching transient overvoltage (SOV) in an offshore wind farm (OWF) by analyzing multiple ignitions of a vacuum circuit breaker. The statistical features of transient overvoltages, which occur under real switching operation scenarios, are analyzed based on the measurements in a laboratory platform that is built according to the configuration of an actual OWF. Next, an OWF simulation transient model is established considering high-frequency characteristics of circuit breakers, which is verified to be able to calculate the SOV accurately. Based on the developed OWF simulation model, the occurrence mechanism of SOV is discussed in detail by studying characteristics of transient voltage and current during multiple ignitions within a vacuum circuit breaker when it is switched OFF. Then, the key impact factors of switching-OFF induced overvoltage are identified, which include the inter-phase capacitance of cable in a windmill tower, the actual operating capacity of a wind turbine generator, and the single-phase inlet capacitance in terminals of a wind turbine transformer. Finally, the recommended configurations are given for the transient mitigation in an OWF. INDEX TERMS Offshore wind farm, switching overvoltage, multiple ignitions, occurrence mechanism, vacuum circuit breaker.

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Section: Accurate Modeling Of Offshore Wind Farmsmentioning

confidence: 99%

Section: Accurate Modeling Of Offshore Wind Farmsmentioning

confidence: 99%

Section: ) Steepness Calculation Of Sov Induced By Vccmentioning

confidence: 99%

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Impact Factor Identification for Switching Overvoltage in an Offshore Wind Farm by Analyzing Multiple Ignition Transients

et al. 2019

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“…The HF current starts with a high rate of change that the VCB cannot turn off. However, with the attenuation of HF current, when the di/dt is less than a critical value when the current is crossing zero, the VCB will cut off HF current and turn it into a disconnected state, which is generally between 100-600 A/µs [24].…”

Section: Hf Arc Quenching Capabilitymentioning

confidence: 99%

Study on Transient Overvoltage of Offshore Wind Farm Considering Different Electrical Characteristics of Vacuum Circuit Breaker

Zhou

Guo

Jiang

et al. 2019

JMSE

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For the study of transient overvoltage (TOV) in an offshore wind farm (OWF) collector system caused by switching off vacuum circuit breakers (VCBs), a simplified experimental platform of OWF medium-voltage (MV) cable collector system was established in this paper to conduct switching operation tests of VCB and obtain the characteristic parameters for VCB, especially dielectric strength parameters; also, the effectiveness of the VCB reignition model was verified. Then, PSCAD/EMTDC was used to construct the MV collector system of the OWF, and the effects of normal switching and fault switching on TOV amplitude, steepness, and the total number of reignition of the VCB were studied, respectively, with the experimental parameters and traditional parameters of dielectric strength of the VCB. The simulation results show that when the VCB is at the tower bottom, the overvoltage amplitude generated by the normal switching is the largest, which is 1.83 p.u., and the overvoltage steepness of the fault switching is the largest, up to 142 kV/μs. The overvoltage amplitude and steepness caused by switching off VCB at the tower bottom faultily with traditional parameters are about 2 and 1.5 times of the experimental parameters under the same operating condition.

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“…It was found that the simulation results can be improved greatly if an appropriate VCB model was included in PSCAD, whereas little improvement was found in DigSILENT. Based on the above discoveries, the authors of [9][10][11][12][13] used a PSCAD/EMTDC simulation to calculate TOVs when VCBs were operated in different configurations, and the results showed that TOVs were affected by many factors, such as the operating scenarios of OWFs, the transformer locations, the cable length, and the wave propagations in the cables.…”

Section: Introductionmentioning

confidence: 99%

Analysis of Switching Transients during Energization in Large Offshore Wind Farms

et al. 2018

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Abstract:In order to study switching transients in an offshore wind farm (OWF) collector system, we employ modeling methods of the main components in OWFs, including vacuum circuit breakers (VCBs), submarine cables, and wind turbine transformers (WTTs). In particular, a high frequency (HF) VCB model that reflects the prestrike characteristics of VCBs was developed. Moreover, a simplified experimental system of an OWF electric collection system was set up to verify the developed models, and a typical OWF medium voltage (MV) cable collection system was built in PSCAD/EMTDC based on the developed models. Finally, we investigated the influences of both the initial closing phase angle of VCBs and typical system operation scenarios on the amplitude and steepness of transient overvoltages (TOVs) at the high-voltage side of WTTs.

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Modeling and Mitigation for High Frequency Switching Transients Due to Energization in Offshore Wind Farms

Cited by 18 publications

References 22 publications

Impact Factor Identification for Switching Overvoltage in an Offshore Wind Farm by Analyzing Multiple Ignition Transients

Impact Factor Identification for Switching Overvoltage in an Offshore Wind Farm by Analyzing Multiple Ignition Transients

Study on Transient Overvoltage of Offshore Wind Farm Considering Different Electrical Characteristics of Vacuum Circuit Breaker

Analysis of Switching Transients during Energization in Large Offshore Wind Farms

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