Your search keyword '"Guzman, Hugo"' showing total 6 results

1. Open-Phase Fault-Tolerant Direct Torque Control Technique for Five-Phase Induction Motor Drives.

Author

Bermudez, Mario, Gonzalez-Prieto, Ignacio, Barrero, Federico, Guzman, Hugo, Duran, Mario J., and Kestelyn, Xavier

Subjects

FAULT-tolerant control systems, INDUCTION motors -- Automatic control, TORQUE control, MOTOR drives (Electric motors), INDUCTION motors, ELECTRIC windings

Abstract

Direct torque control (DTC) has been widely used as an alternative to traditional field-oriented control (FOC) methods for three-phase drives. The conventional DTC scheme has been successfully extended to multiphase drives in recent times, using hysteresis regulators to independently track the desired torque and flux in symmetrical five-phase induction machines (IMs). The fault-tolerant capability of multiphase drives is an interesting intrinsic advantage for safety-critical applications, where recent research has demonstrated the effectiveness of FOC schemes to perform ripple-free postfault operation. In spite of the utility of DTC methods in normal operation of the multiphase machine, no extension to manage the postfault operation of the drive is found in the literature. In this paper, a novel fault-tolerant DTC scheme is presented. The performance of the proposed method is experimentally validated in a five-phase IM drive considering an open-phase fault condition. Provided tests analyze steady and transient states, including the transition from pre- to postfault operation. Obtained results prove the interest of the proposal, which ensures the open-phase fault-tolerant capability of DTC-controlled five-phase IM drives. [ABSTRACT FROM AUTHOR]

Published

2017

2. Impact of Postfault Flux Adaptation on Six-Phase Induction Motor Drives With Parallel Converters.

Author

Gonzalez-Prieto, Ignacio, Duran, Mario J., Barrero, Federico, Bermudez, Mario, and Guzman, Hugo

Subjects

ELECTRIC flux, INDUCTION motors, ROTARY converters, FAULT tolerance (Engineering), ELECTRIC generators, ELECTRIC windings

Abstract

The redundancy of multiphase drives provides an inherent fault-tolerant capability that is appreciated in applications with a complicated corrective maintenance or safety-critical requirements. Fault restrictions, however, force the system to be reconfigured to operate in a smooth and efficient manner. Previous works have been focused on the optimization of current waveforms to generate an undisturbed operation but still maintaining the prefault rated flux settings. This study shows that efficient controllers can improve the postfault performance in six-phase induction machines supplied by parallel-connected converters if offline optimization is used to obtain a variable reference flux. Theoretical and experimental results confirm that the proposed flux adaptation method provides higher torque/power capability, lower degree of imbalance in the current sharing between windings and efficiency improvement. [ABSTRACT FROM AUTHOR]

Published

2017

3. Comparative Study of Predictive and Resonant Controllers in Fault-Tolerant Five-Phase Induction Motor Drives.

Author

Guzman, Hugo, Duran, Mario J., Barrero, Federico, Zarri, Luca, Bogado, Blas, Gonzalez Prieto, Ignacio, and Arahal, Manuel R.

Subjects

*INDUCTION motors -- Automatic control, *RADIO frequency, *PREDICTIVE control systems, *FAULT tolerance (Engineering), *PID controllers, *HYSTERESIS

Abstract

One of the most attractive features of multiphase machines is the fault-tolerant capability due to the higher number of phases. Different postfault control strategies based on hysteresis, proportional integral (PI)-resonant, and predictive techniques have been recently proposed. They all proved their capabilities to withstand fault situations and to preserve the fundamental component of the air-gap field, while achieving minimum losses, maximum torque per ampere, and reducing torque vibrations. Nonetheless, due to their recent introduction, no thorough study has yet appeared comparing the performance of these controllers. In this paper, two open-phase fault-tolerant control schemes are experimentally compared in a real five-phase induction machine. The controllers being compared are based on PI-resonant and predictive control techniques, respectively. The experiments include pre- and postfault situations. Obtained results show that both control methods offer nearly the same performance. When compared, predictive control provides faster control response and superior performance at low-speed operation but is found to be less resilient to fault detection delays and to have higher current ripple. Regarding the controller implementation, it is shown that the transition from prefault to postfault operation involves modeling the nonlinear effects observed when an open-phase fault occurs for the predictive controller and proper retuning of the PI trackers for the PI-resonant controller, to ensure postfault operation. [ABSTRACT FROM AUTHOR]

Published

2016

4. Optimal Fault-Tolerant Control of Six-Phase Induction Motor Drives With Parallel Converters.

Author

Duran, Mario J., Gonzalez Prieto, Ignacio, Bermudez, Mario, Barrero, Federico, Guzman, Hugo, and Arahal, Manuel R.

Subjects

INDUCTION motor efficiency, WINDING machines, CASCADE converters, LOW voltage systems, FAULT tolerance (Engineering), OPTIMAL control theory

Abstract

Multiphase drives and parallel converters have been recently proposed in low-voltage high-power applications. The fault-tolerant capability provided by multiphase drives is then extended with parallel converters, increasing their suitability for safety-critical and renewable uses. This advantageous feature, compared with standard three-phase drives, has been analyzed in the event of open-phase faults. However, when using parallel converters, a converter fault does not necessarily imply an open-phase condition, but usually just a limited phase current capability. This paper analyzes the fault-tolerant capability of six-phase drives with parallel converter supply. Different scenarios considering up to three faults for single and two neutral configurations are examined, optimizing offline the postfault currents and modifying accordingly the control strategies. Experimental results confirm the smooth transition from prefault to postfault situation and the enhanced postfault torque capability. [ABSTRACT FROM AUTHOR]

Published

2016

5. IGBT-Gating Failure Effect on a Fault-Tolerant Predictive Current-Controlled Five-Phase Induction Motor Drive.

Author

Guzman, Hugo, Barrero, Federico, and Duran, Mario J.

Subjects

*INDUCTION motors, *INSULATED gate bipolar transistors, *PREDICTIVE control systems, *FAULT tolerance (Engineering), *ELECTRIC current converters

Abstract

Multiphase machine drives are gaining importance in high-reliability applications due to their fault-tolerance capability and their ability to cope with the postfault operation without any extra electronic components. Predictive current controllers have been recently proposed for managing postfault operation of these drives when an open-phase fault is considered. However, the faulty situation assumes zero stator current while freewheeling diodes can continue conducting in a noncontrolled mode. This work analyzes the postfault operation of the five-phase drive when the freewheeling diodes of the faulty phase are still conducting. Experimental results are provided using a conventional insulated-gate bipolar transistor (IGBT)-based multiphase power converter to quantify the effect of the freewheeling diodes, when an IGBT-gating fault occurs, on the model-based predictive current-controlled drive. [ABSTRACT FROM PUBLISHER]

Published

2015

6. Speed Control of Five-Phase Induction Motors With Integrated Open-Phase Fault Operation Using Model-Based Predictive Current Control Techniques.

Author

Guzman, Hugo, Duran, Mario J., Barrero, Federico, Bogado, Blas, and Toral, Sergio

Subjects

*AUTOMOBILE engines, *SYSTEMS design, *AUTOMATIC control systems, *FAULT tolerance (Engineering), *FAULT-tolerant computing

Abstract

Fault tolerance is one of the most interesting features in stand-alone electric propulsion systems. Multiphase induction motor drives are presented like a better alternative to their three-phase counterparts because of their capability to withstand faulty situations, ensuring the postfault operation of the drive. Finite-control set model-based predictive control (FCS-MPC) has been introduced in the last decade like an interesting alternative to conventional controllers for the electrical torque and current regulation of multiphase drives. However, FCS-MPC strategies for multiphase drives with the ability to manage pre- and postfault operations have not been addressed at all. This paper proposes a fault-tolerant speed control for five-phase induction motor drives with the ability to run the system before and after an open-phase fault condition using an FCS-MPC strategy. Experimental results are provided in order to validate the functionality of the proposed control method, maintaining rated currents and ensuring fast and ripple-free torque response. [ABSTRACT FROM PUBLISHER]

Published

2014