Investigation of the circuit breaker reignition overvoltages caused by no‐load transformer switching surges

Popov, Marjan; Sluis, L. van der; Paap, G.C.

doi:10.1002/etep.4450110609

Cited by 44 publications

(36 citation statements)

References 14 publications

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“…When the transient recovery voltage (TRV) exceeds the DS, prestrikes occur. The recovery of DS is modeled based on Equation (1) provided by [19]. It shows a linear relationship between the value of DS (U dw ) and the time (t):…”

Section: Modeling Of Vacuum Circuit Breakersmentioning

confidence: 99%

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

2016

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This paper presents a comprehensive investigation on high frequency (HF) switching transients due to energization of vacuum circuit breakers (VCBs) in offshore wind farms (OWFs). This research not only concerns the modeling of main components in collector grids of an OWF for transient analysis (including VCBs, wind turbine transformers (WTTs), submarine cables), but also compares the effectiveness between several mainstream switching overvoltage (SOV) protection methods and a new mitigation method called smart choke. In order to accurately reproduce such HF switching transients considering the current chopping, dielectric strength (DS) recovery capability and HF quenching capability of VCBs, three models are developed, i.e., a user-defined VCB model, a HF transformer terminal model and a three-core (TC) frequency dependent model of submarine cables, which are validated through simulations and compared with measurements. Based on the above models and a real OWF configuration, a simulation model is built and several typical switching transient cases are investigated to analyze the switching transient process and phenomena. Subsequently, according to the characteristics of overvoltages, appropriate parameters of SOV mitigation methods are determined to improve their effectiveness. Simulation results indicate that the user-defined VCB model can satisfactorily simulate prestrikes and the proposed component models display HF characteristics, which are consistent with onsite measurement behaviors. Moreover, the employed protection methods can suppress induced SOVs, which have a steep front, a high oscillation frequency and a high amplitude, among which the smart choke presents a preferable HF damping effect.

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Section: Modeling Of Vacuum Circuit Breakersmentioning

confidence: 99%

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

2016

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“…The losses were calculated from the inductance matrix and the capacitance matrix [12]. The impedance and admittance matrices and are then (14) In (14), the second term in the first equation corresponds to the Joule losses taking into account the skin effect in the copper conductor and the proximity effect. The second term in the second equation represents the dielectric losses.…”

Section: B Determination Of the Transformer Parameters 1) Capacitancementioning

confidence: 99%

“…The second term in the second equation represents the dielectric losses. In (14), is the distance between layers; is the conductor conductivity; and is the loss tangent of the insulation.…”

Section: B Determination Of the Transformer Parameters 1) Capacitancementioning

confidence: 99%

“…Multiple reignitions can occur during the switching of transformers and motors with vacuum CBs (VCBs), because of the ability of VCBs to interrupt high-frequency currents. The development process of multiple reignitions has been traced in detail [14], [15]. It has been shown that the problem is not caused by the VCB or the transformer, but by an interaction of both [10].…”

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confidence: 99%

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Analysis of Very Fast Transients in Layer-Type Transformer Windings

Popov

Sluis

Smeets

et al. 2007

IEEE Trans. Power Delivery

120

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“…However, this alternative model is still limited as it is not capable of taking into account core non-linear effects [13]. It is known that the non-linear B-H characteristics of the steel results in a shift in frequency and magnitude of the impedance frequency responses up to several tens of kHz, depending on the transformer terminal conditions [14], [15]. These changes in frequency response characteristics may substantially impact the conditions prior to a fast transient event, e.g.…”

Section: Introductionmentioning

confidence: 99%

Wideband Transformer Modeling Including Core Nonlinear Effects

Gustavsen

2016

IEEE Trans. Power Delivery

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Investigation of the circuit breaker reignition overvoltages caused by no‐load transformer switching surges

Cited by 44 publications

References 14 publications

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

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

Analysis of Very Fast Transients in Layer-Type Transformer Windings

Wideband Transformer Modeling Including Core Nonlinear Effects

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