Open‐circuit fault‐tolerant operation of permanent magnet synchronous generator drives for wind turbine systems using a computationally efficient model predictive current control

Abstract: Model predictive fault-tolerant current control (MPFTCC) of permanent magnet synchronous generator (PMSG) drives can make a valuable contribution to improving the reliability and availability levels of wind turbines, because back-to-back (BTB) converters are prone to failure. However, MPFTCC suffers from excessive computational burden, because the BTB converter is treated as one system where all feasible voltage vectors (VVs) are used for prediction and evaluation. Accordingly, a computationally efficient MPFT… Show more

“…Another modern MV-DMPC-based MSC CB [48] realizes a significantly better current quality by offering a smaller THD of 1.19% than the MPC-FTCC (i.e. 3.27%) [47]. However, the proposed control technique applies a sampling frequency of 10 kHz, which is higher than that used for the conventional methods [45,47].…”

“…The SC in the outer loop of MSC CB in Figure 5 operates the PMSG at the optimum ω r by controlling the reference q ‐axis current ( I * sq ) [47]. The extensively used control technique for the SC in the outer loop of MSC CB (Figure 5) is PI control [32, 45], which regulates the torque‐controlling reference q ‐axis current component ( I * sq ) as [32]: $$\begin{equation}I_{sq}^* = \left( {{K_P} + \left( {{{{K_I}} \mathord{\left/ {\vphantom {{{K_I}} s}} \right.$$…”

“…The advanced MPC‐FTCC with an open circuit fault‐tolerant capability for the MSC is proposed in [47]. Both the MSC and GSC are controlled separately in each sampling period to ensure a stable post‐fault operation of the WT.…”

“…Similarly, to avoid the traditional PI control [37], the modern SCs/QCs for the RSC CB are applied using adaptive backstepping control [38], FLC-sliding mode control (FLC-SMC) [39], H ∞ control [40], FLC-SMC using particle swarm optimization (PSO)-gravitational search algorithm (GSA) [41], recursive least squares (RLS) control [42], non-linear adaptive control (NAC) [43] and model-assisted active disturbance rejection control (MA-ADRC) [44]. The endorsed state-of-the-art CCs for the MSC CB are accomplished using wavelet-NN (WNN) control [45], integral SMC (ISMC) [46], MPC with fault-tolerant current control (MPC-FTCC) [47] and MPC [48]. Correspondingly, the advanced control techniques for the CC of RSC CB are PI-resonant (PIR) control [49], proportional-resonant (PR) control [50], H ∞ control [51], ISMC [52] and finite control set (FCS)-MPC [53].…”

A state‐of‐the‐art comprehensive review of modern control techniques for grid‐connected wind turbines and photovoltaic arrays distributed generation systems

“…Another modern MV-DMPC-based MSC CB [48] realizes a significantly better current quality by offering a smaller THD of 1.19% than the MPC-FTCC (i.e. 3.27%) [47]. However, the proposed control technique applies a sampling frequency of 10 kHz, which is higher than that used for the conventional methods [45,47].…”

“…The SC in the outer loop of MSC CB in Figure 5 operates the PMSG at the optimum ω r by controlling the reference q ‐axis current ( I * sq ) [47]. The extensively used control technique for the SC in the outer loop of MSC CB (Figure 5) is PI control [32, 45], which regulates the torque‐controlling reference q ‐axis current component ( I * sq ) as [32]: $$\begin{equation}I_{sq}^* = \left( {{K_P} + \left( {{{{K_I}} \mathord{\left/ {\vphantom {{{K_I}} s}} \right.$$…”

“…The advanced MPC‐FTCC with an open circuit fault‐tolerant capability for the MSC is proposed in [47]. Both the MSC and GSC are controlled separately in each sampling period to ensure a stable post‐fault operation of the WT.…”

“…Similarly, to avoid the traditional PI control [37], the modern SCs/QCs for the RSC CB are applied using adaptive backstepping control [38], FLC-sliding mode control (FLC-SMC) [39], H ∞ control [40], FLC-SMC using particle swarm optimization (PSO)-gravitational search algorithm (GSA) [41], recursive least squares (RLS) control [42], non-linear adaptive control (NAC) [43] and model-assisted active disturbance rejection control (MA-ADRC) [44]. The endorsed state-of-the-art CCs for the MSC CB are accomplished using wavelet-NN (WNN) control [45], integral SMC (ISMC) [46], MPC with fault-tolerant current control (MPC-FTCC) [47] and MPC [48]. Correspondingly, the advanced control techniques for the CC of RSC CB are PI-resonant (PIR) control [49], proportional-resonant (PR) control [50], H ∞ control [51], ISMC [52] and finite control set (FCS)-MPC [53].…”

A state‐of‐the‐art comprehensive review of modern control techniques for grid‐connected wind turbines and photovoltaic arrays distributed generation systems

“…In back-to-back systems, another possible solution is the sharing of a converter leg between the two converters to improve the post-fault performance of the system [40,[56][57][58][59][60]. This effectively reduces the back-to-back converters to a 5-leg configuration but allows acceptable performance after a fault occurs.…”

Fault Analysis and Non-Redundant Fault Tolerance in 3-Level Double Conversion UPS Systems Using Finite-Control-Set Model Predictive Control

Optimal predictive voltage control of a wind driven five phase PMSG system feeding an isolated load