Showing total 415 results

1. Best Papers and Star Reviewers.

Subjects

*TURBINE generators, *ELECTRIC machines, *MACHINE performance, *WIND power, *MACHINE design

Published

2021

2. Modelling of Wind Turbine Operation for Enhanced Power Electronics Reliability.

Author

Ahmedi, Arsim, Barnes, Mike, Levi, Victor, Carmona Sanchez, Jesus, Ng, Chong, and McKeever, Paul

Subjects

RELIABILITY of electronics, POWER electronics, WIND turbines, THERMOCYCLING, BIPOLAR transistors

Abstract

Enhancing power electronics (PE) converter reliability is crucial for ensuring a reliable operation of current and future operating Wind Turbines (WTs). Achieving high reliability of variable speed WT PE systems requires careful consideration of their operation, and particularly their thermal cycling. This paper presents a methodology for evaluating and reconsidering operational strategies of WTs with relation to the thermal loading and lifetime consumption of the converter. The methodology is applied to compare control strategies for the WT generator and evaluate their impact on the converter reliability by observation of the thermal cycles and by calculating the resultant lifetime consumption of those stress cycles. The thermal stress on both the Machine Side Converter (MSC) and the Grid Side Converter (GSC) is examined and compared. It is shown that the least reliable of the three evaluated control strategies is the one that tracks the power curve below rated speed most closely. This paper suggests that dynamic transients associated with the WT control largely influence the IGBT module wear-out and their modelling needs to be prioritized for lifetime studies. These dynamic transients are captured by the improved model whose value is confirmed for the comparisons in the case study of the paper. [ABSTRACT FROM AUTHOR]

Published

2022

3. An Effective Non-Square Matrix Converter Based Approach for Active Power Control of Multiple DGs in Microgrids: Experimental Implementation.

Author

Sadooghi, Ramin, Niknam, Taher, Sheikh, Morteza, Askarpour, Mohammad, Roustaei, Mahmoud, Chabok, Alireza, and Aghaei, Jamshid

Subjects

MATRIX converters, REACTIVE power, DISTRIBUTED power generation, MICROGRIDS, CASCADE converters

Abstract

In this paper, a new modulation strategy based on the carrier-based switching strategy for the non-square direct matrix converters (MC) is proposed to control the active power of distributed generation (DG) units. In this strategy, the active power of DGs is controlled by the central input current control of the non-square direct MC independent from the voltage and frequency. Conventionally, each DG has a converter, and for supplying a load with N number of DGs, N number of converters are needed and each converter has its own modulation switching and control strategy to control the power output of each DG. Needless to say, in a microgrid with N number of DGs, the control strategy of each converter has more complex structure than that of a microgrid with one converter, and surely the former strategy entails more volume and price. Using the proposed converter in this paper, it is possible to supply a load with N number of DGs through one converter. Also, the power outputs of all DGs are controlled by a central control strategy. The proposed central control strategy is described and simulated for a typical microgrid. Experimental and simulation results validate the effectiveness of the proposed converter and the proposed strategy. The results demonstrate the applicability and efficiency of the system and verify the theoretical analysis. [ABSTRACT FROM AUTHOR]

Published

2022

4. Stability Analysis and Impedance Reshaping Method for DC Resonance in VSCs-based Power System.

Author

Nian, Heng, Yang, Jun, Hu, Bin, Jiao, Yingzong, Xu, Yunyang, and Li, Meng

Subjects

TIME delay systems, RENEWABLE energy sources, IMPEDANCE control, STABILITY theory, VOLTAGE-frequency converters

Abstract

With the rapid growth of renewable energy and power electronic loads, voltage source converters (VSCs) have been commonly applied in different VSCs-based power systems, which also bring in stability issues due to their power electronic characteristics. The impedance-based stability theory and corresponding reshaping method can be used to analyze and solve system stability issue. However, dc stability issue in VSCs-based power systems becomes more complicated when considering ac/dc coupling relationship. This paper proposes an improved reshaping control strategy based on the detailed impedance model considering grid impedance and control delay. The influence of grid impedance, control delay and control parameters of VSC on dc stability are further analyzed to identify the cause of potential resonance risk. The proposed impedance reshaping method considers the trade-off between stability improvement and control performance, and compensates the impacts of grid impedance and control delay at the same time. The validity of stability analysis and reshaping method is further verified through the simulation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2021

5. Loss and Thermal Analysis for High-Speed Amorphous Metal PMSMs Using 3-D Electromagnetic-thermal Bi-Directional Coupling.

Author

Tong, Wenming, Sun, Ruolan, Li, Shiqi, and Tang, Renyuan

Subjects

METALLIC glasses, THERMAL analysis, ELECTROMAGNETS, MAGNETS, TEMPERATURE distribution, MECHANICAL properties of condensed matter, BISMUTH

Abstract

To research the impact of temperature-dependent characteristics of windings and magnets on the electromagnetic power loss and thermal properties of high-speed (HS) interior permanent magnet synchronous machines (PMSMs), an electromagnetic-thermal bi-directional coupling method (BDCM) is proposed for water-cooled HS PMSMs considering the assembling gaps between the motor components in this paper. The electromagnetic power loss is calculated by 3-D transient finite-element method and loaded into the 3-D temperature field according to the actual loss distribution, and the materials’ properties are in turn updated according to the temperature distributions. The loss and temperature calculation results of a 15kW HS amorphous metal PMSM are calculated by two different coupling methods in the conditions of the rated-load sinusoidal supply and converter supply, and compared with the measured results in the case of converter supply. The results obtained by the BDCM are more consistent with the experiment results, verifying the superiority of the proposed analyzing method in improving the calculation accuracy of motor loss and temperature rise. In addition, the applicable conditions of the proposed method are also summarized in the paper. [ABSTRACT FROM AUTHOR]

Published

2021

6. Distributed Optimal Control of DC Microgrid Considering Balance of Charge State.

Author

Huang, Bonan, Zheng, Shun, Wang, Rui, Wang, Huan, Xiao, Jiangfang, and Wang, Peng

Subjects

ROBUST control, MICROGRIDS, ENERGY storage

Abstract

State-of-charge (SoC) imbalance and bus voltage deviation are two of the main problems in autonomous dc microgrids. Based on this concern, this paper presents an improved dual-quadrant SoC weighted control strategy and a distributed optimization control method to achieve SoC balance, ensuring accurate power-sharing and bus voltage recovery. Firstly, this paper couples the injected/released power with the current SoC and observed average SoC value to weight the droop coefficient, which is based on the charge/discharge mode for the energy storage system. Then a secondary controller is designed based on distributed optimal control to eliminate the bus voltage deviation caused by the line impedance difference. The proposed optimal control method optimizes the average bus voltage to the nominal value and achieve accurate power-sharing by constructing the correlated variables and voltage independent intermediate variables exchanged among bulk energy storage units (ESUs). Since the voltage observer cannot accurately observe the true average bus voltage under the communication delay, the proposed distributed optimal control method without the voltage observer can ensure that the average bus voltage is optimized to the nominal value, thus improving the robustness of the control system. Finally, the correctness and effectiveness of the proposed method are verified in Simulink/MATLAB. [ABSTRACT FROM AUTHOR]

Published

2022

7. Cycloidal Magnetic Gear Combining Axial and Radial Topologies.

Author

Duan, Godwin, Gupta, Tanish, Sutton, Edward, Wang, Matthew, Gardner, Matthew C., Khan, Salek A., and Praslicka, Bryton

Subjects

MAGNETISM, TORQUE control, GEARING machinery, TOPOLOGY

Abstract

Axial flux and radial flux cycloidal permanent magnetic gears are characterized by high gear ratios and high torque densities; however, their rotors experience large unbalanced forces, which stress the bearings used in the gear. This paper presents a new cycloidal magnetic gear topology that combines the radial and axial flux topologies. The paper analyzes the forces and torques contributed by the axial and radial magnets in this topology using 3D finite element analysis. It was found that the perpendicular force is necessary to transfer torque to the high-speed shaft and, thus, cannot be cancelled out, but the eccentric component of the magnetic forces can be largely cancelled out, potentially reducing bearing losses and increasing the lifespan of the bearings used in the gear. A proof-of-concept prototype was constructed. Experimental slip torque results matched 3D finite element analysis (FEA) simulations to within 15%, and testing showed that no-load losses were reduced and the slip torque was increased by combining both axial and radial topologies, compared to using an axial configuration alone. [ABSTRACT FROM AUTHOR]

Published

2022

8. An Improved Subdomain Model for Predicting the Magnetic Field of a Motor Containing Non-Orthogonal Boundaries.

Author

Dong, Lieyi, Li, Wanyou, and Shuai, Zhijun

Subjects

MAGNETIC fields, PERMANENT magnets, PERMANENT magnet motors, AIR gap flux, ACTINIC flux, FINITE element method

Abstract

In this paper, the boundary discretization method is used to improve the traditional subdomain model. The improved model can be used to calculate the magnetic field distribution in the region containing non-orthogonal boundary, avoiding the influence of the simplified stator slot or permanent magnet shape on the results in calculating the motor magnetic field using the traditional subdomain model. In addition, the improved subdomain model can also be used to calculate the air-gap flux density when the rotor is eccentric, instead of segmenting the air-gap to an equivalent state without eccentricity. The calculation object of this paper is a surface-mount permanent magnet motor with a rectangular stator slot. The air-gap flux density under no-load and load conditions is calculated, respectively. Since the improved subdomain model does not need to simplify the stator slot shape, the magnetic potential in the stator slot is also calculated. Finally, the air-gap flux density under rotor eccentricity is calculated, and the influence of the calculating parameters on the results of the improved subdomain model is discussed. All the calculated results are compared with those obtained by the finite element method, which verifies the accuracy of the improved calculation model. [ABSTRACT FROM AUTHOR]

Published

2022

9. Optimal Virtual Inertia Design for VSG-Based Motor Starting Systems to Improve Motor Loading Capacity.

Author

Tao, Liang, Zha, Xiaoming, Tian, Zhen, and Sun, Jianjun

Subjects

VIRTUAL design, SYNCHRONOUS generators, VOLTAGE references, ENERGY storage, BRUSHLESS direct current electric motors, SYNCHRONOUS electric motors, ELECTRIC capacity, INERTIA (Mechanics)

Abstract

Virtual synchronous generator (VSG)-based control approaches for AC machine drivers have attracted much attention in recent years. The contradiction between the strong motor loading capacity and the small DC voltage fluctuation is disregarded in previous studies. A larger virtual inertia is required to raise the torque gain and drive the motor with heavier loads, thus resulting in greater DC voltage variations. A systematic method is proposed for the optimal design of the virtual inertia for VSG-based motor starting systems to achieve the maximal motor loading capacity and the low DC voltage fluctuation in this paper. Firstly, the relationship between the virtual inertia and the loading capacity is revealed on the basis of the closed-loop analysis. Considering the DC voltage variation, the constraint on the maximal value of the virtual inertia is proposed from the energy-balance perspective despite the unknown contribution of the DC capacitors to the virtual inertia. To fully exploit the energy storage capacity of the DC capacitors and raise the upper limit of the virtual inertia under the same permitted DC voltage variation, a modified DC voltage reference is introduced. Extensive simulation and experimental results are presented to validate the effectiveness of the proposed methods. [ABSTRACT FROM AUTHOR]

Published

2022

10. The Energy Transition’s Impact on the Accumulated Average Efficiency of Large Hydrogenerators.

Author

Karekezi, Yannick Cyiza, Oyvang, Thomas, and Noland, Jonas Kristiansen

Subjects

HYDROELECTRIC generators, SYNCHRONOUS generators, ECONOMIC impact, SUPPLY chain management, REACTIVE power, WATER power

Abstract

The energy transition is aimed to take advantage of the operational flexibility of hydropower to extend the integration of intermittent renewable sources. Consequently, the hydrogenerators will have to operate in regimes far away from their designed best-point operation. In order to accurately assess the impact, this paper presents a useful approach to determine the overall operating efficiency of synchronous generators under intermittent operation. An accumulated average efficiency (AAE) model is proposed and compared against an alternative approach; the weighted average efficiency (WAE) model. It is found that the WAE approach produces unrealistic low efficiencies when the generator operates in synchronous condenser mode (SCM) for long periods. In general, the AAE supersedes the WAE for all the different load distributions that were investigated. This was further illustrated by a worked example and by constructing more complex load distributions. A load distribution dominated by SCM yields a difference as high as $33.18 \,\%$ , while an even distribution deviates $1.43 \,\%$ in their respective efficiencies. Finally, a yearly on-site measurement of our studied $103 \,\mathrm{MVA}$ generator’s concentrated load distribution revealed a discrepancy of $0.67 \,\%$ , which is a significant deviation considering what the operating regime would mean in terms of economic implications. [ABSTRACT FROM AUTHOR]

Published

2022

11. Information for Authors.

Subjects

PERIODICAL publishing, AUTHORS

Abstract

These instructions give guidelines for preparing papers for this publication. Presents information for authors publishing in this journal. [ABSTRACT FROM AUTHOR]

Published

2022

12. Current Distortion Rejection in PMSM Drives Using an Adaptive Super-Twisting Algorithm.

Author

Garduno, Daniel, Rivas, Jaime J., Castillo, Oscar, Ortega Gonzalez, Ruben, and Gutierrez, Francisco Emilio

Subjects

PERMANENT magnet motors, SYNCHRONOUS electric motors, ALTERNATING current electric motors, SPEED measurements, ALGORITHMS

Abstract

Unavoidably, the controlsystem of any permanent magnet synchronous motor (PMSM) is subjected to perturbations, e.g., motor nonidealities and inverter nonlinearities. To reject these perturbations, a new super-twisting (ST) control variant, called speed adaptive super-twisting (S-AST) control, is proposed in this paper. In the S-AST control, a proportional-integral (PI) and a ST controllers are merged using an adaptive law that is based on the motor speed measurement. This is done to reduce the chattering problems that the standard ST control presents. In addition, a mathematical design for the S-AST control is proposed, where the relationship between the chattering amplitude, the switching frequency and the system perturbations is shown. The main contribution in this paper is the application of the S-AST controller to reduce the total harmonic distortion (THDi) of the PMSM currents. By comparing the S-AST control against PI control, the THDi is reduced from 9.9% to 1.27%, in simulation, and the THDi is reduced from 22.79% to 1.56%, experimentally. These results demonstrate how the S-AST control is an excellent alternative to improve the waveform of the PMSM currents. [ABSTRACT FROM AUTHOR]

Published

2022

13. Application of Superconductors to Suppress Ferroresonance Overvoltage in DFIG-WECS.

Author

Mosaad, Mohamed, Sabiha, Nehmdoh, Abu-Siada, Ahmed, and Taha, Ibrahim

Subjects

WIND energy conversion systems, SUPERCONDUCTORS, INDUCTION generators, SUPERCONDUCTING coils, OVERVOLTAGE, HIGH voltages, MATHEMATICAL optimization, ELECTRIC current rectifiers

Abstract

While much attention was given in the literature to improve the fault ride through (FRT) capability of a doubly-fed induction generator (DFIG)-based wind energy conversion system (WECS) during various faults at the grid side, not much attention was given to investigate and improve the performance of the DFIG-WECS under ferroresonance conditions. This paper investigates the impact of ferroresonance on the overall performance of a DFIG-WECS. The paper also presents a new technique to improve the high voltage ride through capability of the investigated system under such condition. The proposed technique relies on incorporating a superconducting coil within the dc-link of the DFIG grid-side and rotor-side converters. Energy exchange between the coil and the system is controlled through regulating the duty cycle of the dc-chopper interfacing the coil with the dc-link. In this regard, a simple but yet effective proportional-integral (PI) controller is employed to regulate the dc-chopper duty cycle. Parameters of the PI controller are optimized using elephant herding optimization algorithm. Simulation results verify the effectiveness of the proposed controller in improving the overall performance of a DFIG-WECS during ferroresonance events. [ABSTRACT FROM AUTHOR]

Published

2022

14. Calculation Model of Armature Reaction Magnetic Field of Interior Permanent Magnet Synchronous Motor With Segmented Skewed Poles.

Author

An, Yuansheng, Ma, Conggan, Zhang, Nic, Guo, Yue, Degano, Michele, Gerada, Chris, Bu, Feifei, Yin, Xiangrui, Li, Qiongyao, and Zhou, Shengsen

Subjects

PERMANENT magnet motors, MAGNETIC fields, ARMATURES, PERMANENT magnets, MAGNETIC circuits, SYNCHRONOUS electric motors, TORQUE control, POLISH people

Abstract

In an interior permanent magnet synchronous motor (IPMSM) with segmented skewed poles, the armature reaction magnetic field (AR-MF) changes nonlinearly due to the saturation of the rotor magnetic barrier. Meanwhile, this varies under different excitation currents. As a result, it is difficult to be calculated by means of analytical methods. In this paper, the calculation model of AR-MF of IPMSM is first established by vector superposition method, without considering the saturation effect of rotor and the slotting effect of stator. In the second step, the virtual magnetic field of the rotor is introduced to quantitatively calculate the influence of local inhomogeneous saturation on the AR-MF. The latter is derived by combining both the subdomain method and equivalent magnetic circuit method. The complex relative permeance is also introduced to establish the AR-MF accounting for the stator slotting effect. To validate the AR-MF calculation method proposed, an 8-pole 48-slot IPMSM with segmented skewed poles is considered as a case study, showing a comparison by both with finite element (FE) results and the electromagnetic torque measured on a test bench. The model proposed in this paper shows high accuracy and fast computation with respect to FE analysis. [ABSTRACT FROM AUTHOR]

Published

2022

15. Stabilizing Sets of Current PI Controllers for IM Drives With and Without LC Filter.

Author

Vaishnav, Navneet and Jain, Amit

Subjects

SQUIRREL cage motors, CLOSED loop systems, IDEAL sources (Electric circuits), PULSE width modulation

Abstract

Connection of an LC filter to the output of voltage source inverter (VSI) in squirrel cage induction motor (SQIM) drive converts the pulse-width modulated (PWM) voltages into smooth sinusoidal voltages. However, this connection may lead to closed-loop instability in the rotor flux-oriented (RFO) vector-controlled (VC) SQIM system. The closed-loop stability of the combined SQIM + LC filter (SQLC) system is complex and has not been analyzed properly in the literature. In this paper, a detailed closed-loop stability analysis of the SQLC system has been presented based on stability region (SR) and accordingly the PI gains of VC has been designed. The SR method is adopted to derive the common stability regions for the SQIM system and SQLC system. Thereby, the paper proves that connecting an LC filter in-between the VSI and the SQIM system does not always destabilize the closed-loop system. Further, for an SQLC system, the complete range of current controller gains is obtained at various operating points. The frequency-domain specifications have been used to select a proper stabilizing set and the effect of parametric variation of LC filter on the stabilizing set has also been discussed. The experimental results are provided to validate the analysis. [ABSTRACT FROM AUTHOR]

Published

2022

16. Ultra-Voltage Gain Step-Up DC-DC Converter for Renewable Energy Micro-Source Applications.

Author

Bekkam, Krishna and Karthikeyan, V.

Subjects

DC-to-DC converters, RENEWABLE energy sources, CAPACITOR switching, MOTOR drives (Electric motors)

Abstract

In renewable energy micro-source applications, a wide range of voltage conversion of the step-up converter is an essential part to equalize the typical low voltage of micro-source with DC-bus voltage of Inverter or motor drives. In order to meet this purpose, an ultra-voltage gain step-up DC-DC converter is proposed in this paper. The proposed converter has made an arrangement of the regenerative-boost fed switched inductor and capacitor configurations. Thereby, due to such an organization of structure, the proposed converter can develop an extremely high voltage-gain even at lower duty ratios. In addition, it has the advantage of lower switching stress across all power semi-conductive diodes. Furthermore, this paper describes the steady-state analysis and comparative features of the converter with existing recent literature. Finally, to validate theoretical analysis and test the feasibility and suitability of the proposed ultra-gain converter, the experimental results were observed by a 500 W fabricated prototype. [ABSTRACT FROM AUTHOR]

Published

2022

17. An Accurate Torque Output Method for Open-End Winding Permanent Magnet Synchronous Motors Drives.

Author

Zhou, Ying, Zhang, Shuo, Cui, Xing, Zhang, Chengning, and Li, Xueping

Subjects

PERMANENT magnet motors, ELECTROMAGNETS, PARAMETER identification, ELECTROMOTIVE force

Abstract

To improve the torque accuracy for open-end winding permanent magnet synchronous motor (OEW-PMSM) with common dc bus, it is necessary to eliminate the zero-sequence torque (ZST) caused by zero-sequence current (ZSC) and the third back electromotive force. But the third flux linkage mismatch can enlarge ZSC which causes torque ripple. To deal with the above problem, firstly, a q-axis current injection method combined with deadbeat predictive current control (DPCC) is adopted to inject an extra current into the reference q-axis current. The extra torque generated by this injected current can compensate for ZST. Secondly, to ensure the accuracy of the q-axis injected current, a parameter identification method based on recursive least square (RLS) algorithm with forgetting factor is presented to identify the third flux linkage accurately. The identification value can reduce ZSC and torque ripple under different working conditions. And the accurate q-axis injected current can be obtained to counteract ZST and output accurate torque. Finally, three methods are comparatively analyzed in this paper, namely the traditional DPCC method, the DPCC method with q-axis current injection and the proposed DPCC method based on RLS with forgetting factor. The simulation and experimental results verify the effectiveness of the proposed DPCC method. [ABSTRACT FROM AUTHOR]

Published

2021

18. Axial Flux Topology Based Control Moment Gyroscope for Integrated Speed and Tilt Control.

Author

Kant, Krishan and Kirtley, James L.

Subjects

TORQUE control, GYROSCOPES, MICROSPACECRAFT, TOPOLOGY, SPEED

Abstract

This paper presents a control moment gyroscope (CMG) for small satellites, driven and controlled based on axial flux motor principle. The presented structure is coreless with Halbach array rotor and a stator to control the rotational speed/torque and effective gimbal rate/ angle. This topology allows a relatively simple mechanical structure with an equivalent dual gimbal control for limited angle. There are two sets of windings for torque generation along three orthogonal axes, one is 8 pole and other is 6 pole. The winding structure is novel in the sense of accommodating different number of poles $ (>\!4)$ using the same stator slots. Two 3 phase inverters are used to accurately control the torques by energising two sets of windings. Analytical formulation is provided to understand various torque generation mechanisms and 3D FEM simulations are performed to verify the operation and to get better quantitative torque generation capabilities of the CMG along different axes. Finally, a quick experiment prototype is developed to verify the operation with open loop speed control and closed loop tilt position control more qualitatively with off the shelf available components. Independent control of torque in 3 axes was achieved experimentally and the results are explained. [ABSTRACT FROM AUTHOR]

Published

2021

19. Field Enhancing Model Predictive Direct Torque Control of Permanent Magnet Synchronous Machine.

Author

Zhang, Kai, Fan, Mingdi, Yang, Yong, Zhu, Zhongkui, Garcia, Cristian, and Rodriguez, Jose

Subjects

TORQUE control, PERMANENT magnets, PREDICTION models, COST functions, TORQUE

Abstract

For the short-term high torque output, an improved model predictive direct torque control (MPDTC) method with field enhancing is proposed to increase torque. In order to avoid the possible loss of synchronism while increasing torque, the MPDTC method limits the load angle in the cost function. Under the constant load angle limitation, the improved method increases the torque output capability by increasing the magnetic field. This paper starts from the torque calculation, theoretically analyzes the torque-load angle characteristics, and illustrates the flux vector trajectory with the voltage limit circle and current limit circle. The proposed method maintains the dynamic and static performance of the traditional MPDTC method while ensuring the system stability. The experimental results show that the torque capacity of the proposed method has been improved, and it has stable extreme output torque. So, some applications, such as electric load simulators, can choose the motor with small capacity and small inertia, thereby weakening negative effects of the inertia torque. [ABSTRACT FROM AUTHOR]

Published

2021

20. Sensorless Drive Strategy of Open-End Winding PMSM With Zero-Sequence Current Suppression.

Author

Liu, Cheng and Shang, Jing

Subjects

PHASE-locked loops, ELECTROMAGNETS

Abstract

The open-end winding permanent magnet synchronous motor (OW-PMSM) with common DC bus configuration provides a path for zero-sequence current (ZSC). Apart from the zero-sequence voltage (ZSV) generated by inverters modulation, ZSC also comes from the third harmonic back-EMF. However, the third harmonic back-EMF contains the position information of the rotor, which can be extracted by an appropriate strategy to achieve position sensorless drive. In order to achieve sensorless drive and ZSC suppression simultaneously, this paper proposes a novel general-integral extended state observer (GI-ESO) based method. The third harmonic back-EMF of the OW-PMSM is estimated and calculated in three-phase stationary coordinate system by GI-ESO. And then, a single-phase phase lock loop observer (SPLL) is exploited to extract the position and speed information of the rotor. Meanwhile, the estimated third harmonic back-EMF is directly fed forward to SPWM as the ZSV reference, then the output voltages of the inverters contains the ZSV that can exactly counteract the third harmonic back-EMF, so as to realize the suppression of ZSC. Compared with the method of combining the fundamental back-EMF detection and proportional resonance (PR) regulator, this method can realize sensorless drive and ZSC suppression at the same time with only one scheme. Benefiting from the use of GI-ESO, the observer bandwidth can be relatively low, which helps suppress noise and extend the speed range of sensorless operation. Moreover, this method has strong robustness against motor parameters. The proposed strategy is validated by experiments. [ABSTRACT FROM AUTHOR]

Published

2021

21. Gaussian Process Kernel Transfer Enabled Method for Electric Machines Intelligent Faults Detection With Limited Samples.

Author

Chen, Jianjun, Hu, Weihao, Cao, Di, Zhang, Man, Huang, Qi, Chen, Zhe, and Blaabjerg, Frede

Subjects

ARTIFICIAL intelligence, GAUSSIAN processes, ELECTRIC machines, DEEP learning, FAULT diagnosis, INTELLIGENT tutoring systems

Abstract

Traditional Artificial Intelligence (AI) based fault detection approaches need a large amount of data for the model learning. However, in a real-world system, it is very difficult and expensive to obtain massive labeled fault data. In addition, the working conditions of a motor are usually variable, conventional fault diagnosis models with weak generalization ability can only be used for fault detection under constant working condition. The performance of traditional AI based approaches decreases when the working condition changes. To this end, a novel deep Gaussian process (GP) kernel transfer based few-shot learning method (RNGPT) is proposed in this paper for the fault detection of electric machines. First, a deep residual network (ResNet) is used to extract the features of the raw data. Then, the encoded latent feature vector is fed into the GP with kernel transfer ability to make the motor fault detection and classification. The proposed method uses much less data than the traditional AI based method to achieve fault diagnosis under variable working condition, and does not cause an overfitting problem. Experimental results of two case studies demonstrate that the proposed RNGPT model can accurately and effectively detect motor faults with limited labeled data under different working conditions. Experimental results of RNGPT with radial basis function (RBF) kernel model on simulation data present that the fault detection accuracy of the proposed method is about 16% higher than the conventional deep learning methods, 6% higher than other few-shot learning based methods in 5-shot and 4% higher in 1-shot. Finally, experimental on a real-world dataset, the RNGPT-RBF model still has the highest fault diagnosis accuracy in 5-shot (99.39 $ \pm $ 0.09%) and 1-shot (98.55 $ \pm $ 0.16%). [ABSTRACT FROM AUTHOR]

Published

2021

22. 2-D Analytical No-Load Electromagnetic Model for Slotted Interior Permanent Magnet Synchronous Machines.

Author

faradonbeh, Vahid Zamani, Rahideh, A., Taghipour Boroujeni, Samad Taghipour, and Markadeh, Gholamreza Arab

Subjects

COMPUTATIONAL electromagnetics, MAGNETIC flux density, ACTINIC flux, FINITE element method, ELECTROMAGNETIC launchers, MAGNETIC circuits, PERMANENT magnets

Abstract

This paper presents a fast analytical model for estimating the components of the PM flux density distribution in the air-gap for a number of interior permanent magnet synchronous machines (IPMSMs). Deriving the two-dimensional (2-D) analytical model for IPMSMs is more challenging compared to that of surface-mounted permanent magnet synchronous machines (SPMSMs) due to the inconsistent geometry of the rotor in polar coordinates. IPMSMs are usually modeled by using 0-D or 1-D methods such as the magnetic equivalent circuit (MEC); however, the MEC method is unable to take into account the tangential component of the magnetic flux density vector. In this paper, a 2-D analytical no-load electromagnetic model for five rotor topologies of IPMSMs is proposed. The effects of the stator slots on the radial component of the PM flux density distribution in the air-gap are then included by defining an air-gap function. The effects of the stator slots on the tangential components of the PM flux density distribution in the air-gap are also considered by injecting virtual surface currents (VSCs) or virtual permanent magnets (VPMs). For verification purposes, the analytical results are compared with those of the finite element method (FEM) and the experimental results of one of the cases. [ABSTRACT FROM AUTHOR]

Published

2021

23. A Variable Inductor Controlled Single-Stage AC/DC Converter for Modular Multi-Channel LED Driver.

Author

He, Qingqing, Luo, Quanming, Wei, Yuqi, and Sun, Pengju

Subjects

LIQUID crystal displays, ELECTRIC current rectifiers, MULTICHANNEL communication, STREET lighting, ZERO voltage switching, LIGHT emitting diodes, COST control

Abstract

Light-emitting diodes (LEDs) are widely used in street lighting, landscape lighting, liquid crystal display (LCD) backlighting, healthcare, etc. As an important part of LED lighting products, LED driver plays a vital role in maintenance costs reduction, energy saving and lifetime prolongation. In this paper, a single-stage LED driver is proposed, which is integrated by a totem-pole bridgeless power factor correction (PFC) unit and several modular LCL-T resonant rectifiers. The totem-pole bridgeless PFC unit and the LCL-T resonant rectifiers are integrated by sharing switches, which can simplify the circuit and reduce the system cost. The output current can be regulated by applying the variable inductor control. Constant duty cycle and fixed switching frequency operation can be achieved as well. The operating principle and the performance of the proposed converter are analyzed in this paper. In addition, a precise parameter design method is proposed by considering the high-order harmonics. At last, an experimental prototype is established to validate the proposed parameter design and variable inductor control method. [ABSTRACT FROM AUTHOR]

Published

2021

24. A Parameterized Linear 3D Magnetic Equivalent Circuit for Analysis and Design of Radial Flux Magnetic Gears–Part I: Implementation.

Author

Johnson, Matthew, Gardner, Matthew C., and Toliyat, Hamid A.

Subjects

MAGNETIC flux, MAGNETIC circuits, FINITE element method, MAGNETIC torque, TORQUE

Abstract

Magnetic gears can perform the same function as mechanical gears with the added benefits inherent to contactless power transfer. However, quick and accurate analysis tools are required for magnetic gears to reach their full potential. As end effects can significantly impact the slip torque of a magnetic gear, 2D models often overestimate the slip torques, so 3D models are frequently required. Therefore, this paper proposes a 3D linear Magnetic Equivalent Circuit (MEC) or reluctance network model of radial flux magnetic gears with surface mounted magnets. This is an extension of a previously developed 2D MEC model, and, like the previous 2D model, it is thoroughly parametrized so that it can be directly applied to a wide range of parametric cases. This is Part I of a two-part paper and focuses on the implementation of the 3D MEC model. Part II compares the 3D MEC model against nonlinear finite element analysis (FEA) models to validate the MEC model's accuracy and to develop guidelines for discretizing the geometry. [ABSTRACT FROM AUTHOR]

Published

2021

25. IEEE Transactions on Energy Conversion Information for Authors.

Subjects

ENERGY conversion, WEBSITES

Published

2022

26. Model Reference Adaptive System Based Apparent Power Sharing in Inverter Based Microgrids.

Author

Aquib, Mohd., Vijay, A. S., Doolla, Suryanarayana, and Chandorkar, Mukul C.

Subjects

MICROGRIDS, SHARING, INFORMATION networks, REACTIVE power

Abstract

Power sharing amongst sources can be improved in an islanded microgrid by utilizing the information of the network’s impedance. In this paper, an impedance based model reference adaptive system (Z-MRAS) scheme is proposed to estimate the impedance angle for converter based distributed generators (DGs) in the islanded mode. The focus is to enhance the proportional apparent power sharing between the DGs operated using generalized droop control (GDC). The performance of GDC depends on the effective tie-line impedance between the DGs and the proposed MRAS scheme provides the feedback of the estimated impedance angle. The accuracy of the impedance angle estimation is established for various tie-line $X/R$ ratios, and this results in enhanced power sharing performance for balanced, harmonic, unbalanced, dynamic and constant power load cases as well as parallel line and underground cable cases. The proposed method is validated through off-line simulations in MATLAB and controller hardware in loop (CHIL) using real time simulator (Opal-RT) including cases of meshed networks and DG plug and play for a modified CIGRE network. [ABSTRACT FROM AUTHOR]

Published

2022

27. Estimation of Two- and Three-Dimensional Spatial Magnet Temperature Distributions for Interior PMSMs Based on Hybrid Analytical and Lumped-Parameter Thermal Model.

Author

Liang, Dawei, Zhu, Z. Q., Shao, Bo, Feng, Jianghua, Guo, Shuying, Li, Yifeng, and Zhao, Anfeng

Subjects

TEMPERATURE distribution, MAGNETS, EDDY current losses, PERMANENT magnets, FINITE element method, HEAT conduction

Abstract

A hybrid analytical and lumped-parameter thermal model is proposed in this paper to estimate the transient and steady-state two- and three-dimensional (2/3-D) spatial magnet temperature distributions for an interior permanent magnet synchronous machine (IPMSM). On the basis of a lumped-parameter thermal model (LPTM), the magnet analytical thermal models (ATMs) are synergized to establish the hybrid thermal model. By utilizing the transient or steady-state boundary conditions calculated by the LPTM, the ATMs are obtained by solving the heat conduction equations to estimate the spatial magnet temperature distributions in the 2-D horizontal-vertical and axial-vertical planes, which can also be extended to the 3-D temperature distribution by utilizing the multi-slice method. Meanwhile, the non-uniform magnet eddy current loss is also considered. Finally, both electromagnetic-thermal coupled finite element analysis method and experiments are used for verification based on a totally enclosed IPMSM. [ABSTRACT FROM AUTHOR]

Published

2022

28. Broken Rotor Bar and Rotor Eccentricity Fault Detection in Induction Motors Using a Combination of Discrete Wavelet Transform and Teager–Kaiser Energy Operator.

Author

Agah, Gholam Reza, Rahideh, Akbar, Khodadadzadeh, Hosein, Khoshnazar, Seyed Moslehoddin, and Hedayatikia, Shahin

Subjects

INDUCTION motors, SQUIRREL cage motors, WAVELET transforms, ROTORS, TORQUE control, POWER resources, DISCRETE wavelet transforms

Abstract

In this paper, a hybrid approach is proposed to detect the broken rotor bar and rotor mixed eccentricity faults of three-phase squirrel cage induction motors based on one phase of the stator current signal. The hybrid method is based on a combination of discrete wavelet transform (DWT), Teager–Kaiser energy operator (TKEO) and power spectral density (PSD). At the first stage, DWT is applied on the stator current signal; then TKEO is applied on some of the DWT detail coefficients and finally PSD is used to extract the required feature to detect the aforementioned faults. The proposed method is tested on an experimental test-rig having a 1.5 kW induction motor under various load conditions and three different power supplies: 1) directly supplied by power grid; 2) supplied by a drive system based on scalar control technique; and 3) supplied by a drive system based on direct torque control (DTC) technique. The results show the efficacy of the proposed method in accurate detection of the broken rotor bar and rotor mixed eccentricity faults. [ABSTRACT FROM AUTHOR]

Published

2022

29. Vibration Characteristics of Permanent Magnet Motor Stator System Based on Vibro-Inertance Matrix Method.

Author

Li, Quanfeng, Liu, Shichang, and Hu, Yihua

Subjects

PERMANENT magnet motors, STATORS, FINITE element method, TRACTION motors

Abstract

The vibration characteristics of stator system of the interior permanent magnet synchronous motor for EV are deeply studied in this paper, the effectiveness of reducing the vibration by optimizing the vibro-inertance (acceleration admittance) of the stator system is validated. Firstly, the theory of the vibro-inertance matrix of stator system with single-point excitation and multi-point response is proposed, and the mathematical theory model of vibro-inertance matrix of prototype motor stator system is established. Secondly, a new method of 3D finite element method (FEM) be used to simulate and analysis the vibro-inertance's characteristics for the prototype's stator system. Then, the correctness of the theory and the FEM simulation is verified by the prototype source-path-contribution (SPC) experiment. And it is found that near some non-natural frequencies with large vibro-inertance amplitudes, although the amplitude of operating force is relatively small at these frequencies, the prototype still produces large vibrations. Finally, three methods for optimizing the vibro-inertance matrix of the stator system are further studied. These methods can effectively shift the inertance frequency band of the stator system and change the average value of the inertance's amplitude of the motor stator system in different frequency bands, thereby changing the vibration characteristics of the whole motor. [ABSTRACT FROM AUTHOR]

Published

2022

30. Model Predictive Control for ARC Motors Using Extended State Observer and Iterative Learning Methods.

Author

Wang, Jiyao, Huang, Demin, Fang, Shuhua, Wang, Yicheng, and Xu, Wei

Subjects

ITERATIVE learning control, PREDICTION models, POWER density, PERMANENT magnet motors, VARIABLE speed drives, COST functions

Abstract

The arc permanent magnet motor (arc motor) is widely used in large telescope for its high efficiency and high power density. Due to the unique structure, the periodic end torque, cogging torque and flux harmonics will cause certain speed ripples which can affect the performance of the drive system. To solve these problems, the paper proposes a novel model predictive control (MPC) based on extended state observer and iterative learning control, where the MPC is equipped in speed loop and the disturbances estimated by the conventional extended state observer (ESO) are fed forward to the controller to improve the ability of disturbance rejection. A position dependent iterative learning control (ILC) is used to estimate the periodic disturbances at different speeds. The MPC calculates the q axis current reference with the compensation of ESO and ILC, which can have a fast response and disturbance rejection ability for periodic and nonperiodic disturbances. The stability of the proposed method is demonstrated by theoretical analysis. The experimental results validate the effectiveness of the proposed method at different speeds. [ABSTRACT FROM AUTHOR]

Published

2022

31. Nonlinear Analytical Model for Performance Prediction of Eddy Current Recoil Brake.

Author

Li, Jiahao, Yang, Guolai, Sun, Quanzhao, and Wang, Liqun

Subjects

AIR gap flux, MAGNETIC flux leakage, MAGNETIC flux density, SPECIFIC gravity, MAGNETIC circuits

Abstract

In this paper, a nonlinear analysis model for predicting the performance of eddy current recoil brakes (ECRB) is proposed by combining the magnetic equivalent circuit (MEC) model and the subdomain model. The subdomain model introduces the equivalent region to improve the inherent shortcomings of the equivalent current sheet (ECS) method. The outer tube is divided into a magnetic saturated region and an unsaturated region in the subdomain model to simulate the magnetic saturation of the outer tube during recoil. The MEC model is applied to calculate the air gap magnetic flux density and the relative permeability of the equivalent region. Leakage flux and magnetic saturation are considered in the MEC model. The eddy current resistance of ECRB is calculated by the subdomain model. The model is verified by the finite element model, and it is able to predict the performance of ECRB with different structural parameters. In addition, the prototype of the ECRB was manufactured. A test was carried out on a 155 mm artillery to verify the accuracy of the proposed nonlinear analysis model. [ABSTRACT FROM AUTHOR]

Published

2022

32. Multi-Objective Optimization of Interior Permanent Magnet Machine for Heavy-Duty Vehicle Direct-Drive Applications.

Author

Ji, Jinghua, Yang, Yanjiao, Ling, Zhijian, and Zhao, Wenxiang

Subjects

PERMANENT magnets, MAGNETIC structure, ELECTROMOTIVE force, EVOLUTIONARY algorithms, INTERIOR-point methods, MACHINERY, INDUCTION motors

Abstract

In this paper, an interior permanent magnet (IPM) machine is presented and optimized for heavy-duty vehicle direct-drive applications. Since efficiency decrease and serious heating come along with excessive core loss under flux weakening control, a rotor topology with the combination of the eccentricity structure and magnetic barriers is proposed. The key is to achieve the comprehensive optimization of the proposed rotor topology to satisfy the different requirements under diverse operating points. Then, a multi-objective automatic parallel optimization method is applied, which simultaneously analyzes multi-condition operation without weight coefficients defined artificially. The 3D Pareto solution set is generated by using nature inspired evolutionary algorithm based on the high-precision metal-modals of optimal prognosis, which reduce the needed computation cost significantly. Moreover, the back electromotive force total harmonic distortion, torque and core loss of the optimal machine are analyzed at corresponding operating points. Finally, the finite-element results are validated by experiments based on a prototype machine. [ABSTRACT FROM AUTHOR]

Published

2022

33. Online Fault Diagnosis Method for Grid-Connected Inverters Based on Finite-Set Mixed Logical Dynamical Model Prediction.

Author

Lin, Qiongbin, Yu, Kai, Zeng, Xinglan, Zong, Yi, Su, Xianjin, Cai, Fenghuang, and Zhan, Yin

Subjects

DIAGNOSIS methods, ELECTRIC inverters, ENERGY storage, PREDICTION models, ELECTRIC fault location, FAULT location (Engineering), ELECTRICAL energy, FAULT diagnosis

Abstract

The grid-connected inverter is a key device in the renewable energy power generation system and large-scale energy storage system, which the operational stability and reliability are the basis for the efficient and safe application of electrical energy. A real-time fault diagnosis method of a three-phase for grid-connected application combining a mixed logic dynamic (MLD) model and finitecontrol set model predictive control (FCS-MPC) is proposed. This paper not only realizes the open circuit fault diagnosis and location of the switching devices in the main power circuit, but also discusses the threshold issues and post-fault operations. The advantage of the proposed method is that it directly uses the control data and measurement signals of the controller without extra sensors and calculation, which will shorter the fault diagnosis time and occupy less calculation resource of the main processor. Simulation results illustrate the quickness of the fault identification and accurate position with robustness to the interference of the diagnosis method. Finally, the effectiveness of the diagnosis method was verified by a 1500 W experimental prototype in a laboratory. [ABSTRACT FROM AUTHOR]

Published

2022

34. Unified SISO Loop Gain Modeling, Measurement, and Stability Analysis of Three-Phase Voltage Source Converters.

Author

Lin, Jianheng, Su, Mei, Sun, Yao, Xie, Shiming, Xiong, Wenjing, and Li, Xing

Subjects

VOLTAGE-frequency converters, IDEAL sources (Electric circuits), LAPLACIAN matrices, STABILITY criterion, MATHEMATICAL induction, ELECTRON tube grids

Abstract

Frequency-domain modeling is an effective technique in the dynamic analysis of power electronic converters-based power systems. In this paper, a unified single-input single-output (SISO) loop gain modeling for the three-phase grid-tied voltage source converters (VSCs) under both symmetric and asymmetric AC grids is presented, which facilitates the physical measurement and stability analysis. Based on the linear-time-periodic (LTP) modeling technique, the harmonic admittance model of the three-phase grid-tied VSC is developed in the stationary (αβ)-frame, which accurately captures the coupling dynamics. This model can be transformed into other existing models through coordinate transformations. According to the idea of mathematical induction, a two-by-two recursive admittance matrix (RAM) model is derived, which is easy to include frequency coupling components of arbitrary order. It is illustrated that the VSC admittance is coupled with the grid admittance due to the frequency coupling effect (FCE). Furthermore, the RAM is converted to its equivalent SISO models following the concept of loop gain. The system stability is thus assessed by the SISO stability criteria (e.g., Nyquist stability criterion). In addition, the loop gain allows the traditional SISO perturbation and measurement scheme to be used for detecting the stability margin information. Finally, simulation results verify the feasibility and correctness of the theoretical analysis presented above. [ABSTRACT FROM AUTHOR]

Published

2022

35. Power Density Boosting Techniques for Reconfigurable Integrated Modular Motor Drives.

Author

Mohamed, Abdalla Hussein, Vansompel, Hendrik, and Sergeant, Peter

Subjects

POWER density, MOTOR drives (Electric motors), ELECTRIC machines, ELECTRIC motors, FAULT tolerance (Engineering), ELECTRIC power, INDUCTION machinery

Abstract

The electric drive power density and fault tolerance capability are of fundamental importance in many applications such as aerospace and traction applications. The modularization and the physical integration of the electric motor and the power converter components can lead to a high power density and a high fault tolerance drive system. The power density of a highly modular and integrated drive based on an axial flux permanent magnet synchronous machine and GaN converter is investigated in this paper. Several power density boosting techniques are provided and investigated using CFD simulations. These techniques incorporate optimization of the converter topology, the geometry of the shared cooling structure of the electric machine and the power converter and optimal selection of the materials in the path of heat transfer from the machine and the power converter to the cooling ambient. The power density of the reference integrated design is increased from 1.12 kW/ $l$ to 2.14 kW/ $l$. The CFD computations are validated by extensive measurements on a modular integrated setup. [ABSTRACT FROM AUTHOR]

Published

2022

36. A Generalized, Fast and Robust Open-Circuit Fault Diagnosis Technique for Star-Connected Symmetrical Multiphase Drives.

Author

Sun, Jiawei, Li, Chi, Zheng, Zedong, Wang, Kui, and Li, Yongdong

Subjects

FAULT diagnosis, FAULT-tolerant control systems, FAULT location (Engineering), VARIABLE speed drives, ELECTRIC fault location, SIGNAL detection, MACHINE performance

Abstract

Multiphase drives with fault-tolerant capability are favored in high-reliability applications. In most fault-tolerant multiphase drives, the fault types and locations must be known prior to the fault-tolerant control. Therefore, fault diagnosis is an indispensable procedure. This paper proposes a generalized method to detect and identify the open-circuit faults (including open-switch and open-phase faults) in star-connected symmetrical multiphase drives with different phase numbers. The selected fault diagnosis signals are calculated solely from simple arithmetical operations of measured phase currents, resulting in easy real-time implementation. As fault detection signals are derived from the physical constraint imposed by the neutral point, the proposed method is naturally robust and not sensitive to operating points, machine transients and harmonics in stator currents. Therefore, a relatively small fault detection threshold can be used and fast detection can also be achieved. After the fault has been detected, the fault type is further identified according to the polarity of the integration of phase currents. Experimental results on nine-phase and five-phase induction machine drives verify the generality, fast diagnosis speed and robustness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2022

37. Improved Average-Value and Detailed Equivalent Models for Modular Multilevel Converters With Embedded Storage.

Author

Herath, Nuwan and Filizadeh, Shaahin

Subjects

MULTILEVEL models, ELECTRIC transients, RENEWABLE energy sources, STORAGE

Abstract

The paper develops two computationally efficient models, namely a detailed equivalent model and an average-value model, with provisions for representation of the critical state of converter blocking, for modular multilevel converters with embedded storage. These models are indispensable in the simulation of dc faults. The developed detailed equivalent model provides accuracy that matches electromagnetic transient (EMT) simulations, with much reduced computational burden; the developed average-value model represents the averaged behavior of the converter by neglecting switching transients. Both models are extensively evaluated in the context of an HVDC system against benchmark results form a detailed switching model developed in PSCAD/EMTDC. The results confirm the validity and accuracy of the models for steady state, transient, and faulted operating conditions including when the converter is blocked in response to a dc fault. [ABSTRACT FROM AUTHOR]

Published

2022

38. Nonlinear Analytical Modelling for Surface-Mounted Permanent Magnet Motors With Magnet Defect Fault.

Author

Li, Zhaokai, Huang, Xiaoyan, Yu, Yelong, Jiang, Dongdong, Wu, Lijian, and Shi, Tingna

Subjects

PERMANENT magnet motors, MAGNETS, CONFORMAL mapping, FAULT diagnosis, MAGNETIC domain

Abstract

This paper analyzes magnet defect fault signature in the surface-mounted permanent magnet motor (SPMM) using nonlinear analytical model considering the influence of magnet shape and magnetization direction. Based on the surface current method and conformal mapping technique, the magnet defect equivalent current and equivalent nonlinearity current are proposed to represent the magnet defect. Accordingly, the performance of SPMM can be obtained. The proposed model has great potential to investigate SPMM with non-uniform magnet defect and gives theoretical basis for fault diagnosis. The extra sensing coil is added to measure the voltage waveforms, which can also be predicted using the nonlinear analytical model and shows the influence of magnet defect fault. Finally, the finite element analysis and experimental results verify the high accuracy of nonlinear analytical model. [ABSTRACT FROM AUTHOR]

Published

2022

39. Use of Resolvers in Limited Rotations.

Subjects

FINITE element method, TRANSFER functions, ELECTROMAGNETIC noise, ROTATIONAL motion, RELIABILITY in engineering

Abstract

The electromagnetic structure of the resolvers makes them excellent for difficult applications. Among them, axial flux resolvers show better performance against mechanical faults. However, a complicated resolver-to-digital converter (RDC) overshadows the whole system's reliability. Both of the conventional software and hardware decoding methods suffer from deficiencies, such as difficulty to implement, poor performance against electromagnetic noise, expensive equipment, etc. To overcome these challenges any easy-to-implement software-based RDC is suggested in this paper that is used for rotational forth-and-back motions. In fact, instead of the conventional arc-tangent method to extract the position information from sine (SIN) and cosine (COS) signals, three transfer functions are proposed to estimate the position. Tylor's series are used to linearize the transfer functions over the zero position and a transfer function with minimum linearization error over the whole region is selected as opt one. The design process of axial flux resolvers is presented as well. 3-D time-stepping finite element method (FEM) is used to verify the success of the proposed analytical calculations. Finally, prototypes of the different configurations are tested for experimental measurements. [ABSTRACT FROM AUTHOR]

Published

2022

40. Systematic Overview of Active Battery Equalization Structures: Mathematical Modeling and Performance Evaluation.

Author

Qu, Fan, Luo, Quanming, Liang, Huan, Mou, Di, Sun, Pengju, and Du, Xiong

Subjects

MATHEMATICAL models, LITHIUM-ion batteries, COST structure, BATTERY storage plants, ELECTRIC batteries, QUANTITATIVE research

Abstract

With the widespread application of lithium-ion battery packs, it calls for efficient balancing methods to improve the performance of these battery systems. The relevant research has focused on the design of equalization circuits and control strategies while neglecting quantitative analysis and comparison of battery active equalization structures from the systematic level. In this paper, we propose an improved system-theoretic modeling approach for active equalization structures that takes into account the battery's constraints, including equalization current rate and SOC operation range. Accordingly, the mathematical models of various active equalization structures are derived that can describe their equalization dynamic behavior. Then, the analytical algorithms are developed to estimate the balancing time of active equalization structures online. Finally, extensive numerical simulations are conducted to evaluate and compare the average performance of these equalization systems in term of equalization time. It then comes up with a comprehensive comparison among them. Consequently, the Multicell-to-Multicell (MC2MC) balancing structure benefits the fast balancing speed and the lowest sensitive to initial batteries’ SOCs. The global structure has the lowest implementation cost and the series structure benefits the simplest control. Moreover, the module-based structures have faster balancing speed when each module contains about 4–6 batteries. [ABSTRACT FROM AUTHOR]

Published

2022

41. Study on Convection Heat Transfer of End-Winding for a 10 kW External Rotor PMSM With Open End Cap.

Author

Zhang, Xintong, Zhang, Chengming, Li, Liyi, and Fu, Pengrui

Subjects

HEAT convection, HEAT transfer, HEAT transfer coefficient, ROTORS, NUSSELT number

Abstract

The convective heat transfer characteristics of end-winding for a 10 kW external rotor PMSM with open end cap are studied in this paper. A coupling iterative method of CFD and thermal network (TN) is proposed to solve the motor temperatures and convective heat transfer coefficients (CHTC). The variation laws of the CHTCs and heat dissipation proportions of 10 kW motor walls with speed are analyzed. The heat dissipation capacities of the end-winding for motors with open and closed end cap are compared. Based on the CFD results, a fitting formula of end-winding CHTC for external rotor motor with open end cap is constructed, in which the Nusselt number is calculated by the dimensionless parameters composed of the geometric features of the open end cap. The validities of the proposed coupling iterative method and the fitting formula are verified by the temperature rise experiment of the 10 kW prototype. [ABSTRACT FROM AUTHOR]

Published

2022

42. A Computationally Efficient Surrogate Model Based Robust Optimization for Permanent Magnet Synchronous Machines.

Author

Yang, Yongxi, Zhang, Chengning, Bramerdorfer, Gerd, Bianchi, Nicola, Qu, Jianzhen, Zhao, Jing, and Zhang, Shuo

Subjects

ROBUST optimization, PERMANENT magnets, FINITE element method, MANUFACTURING processes, PROCESS optimization, PERMANENT magnet motors

Abstract

One of the main obstacles to the robust optimization for permanent magnet machines is the high computational burden, which is mainly caused by the robustness evaluation process considering the manufacturing uncertainties. In this paper, a sequential sampling Kriging model is adopted to estimate the design robustness, and the problem of high-dimensional variables for the surrogate model due to uncertainties is avoided through adopting the worst-case based approach. To further reduce the number of finite element analyses (FEA) required for constructing a metamodel, a multi-points sequential sampling process with a two-step optimization oriented surrogate model updating algorithm is proposed. Compared with the FEA directly based robust optimization in previous work, similar Pareto Fronts are achieved by adopting the meta-model proposed algorithm but the overall run time reduced by 75%. In the end, an optimization problem for a 1.2 kW motor is considered by applying the proposed algorithm, and two prototypes with deliberately designed tolerances, imitating the worst-case scenarios in the real world, are manufactured. The worst-case torque ripple is reduced from 7.6% to 4.8% after optimizing, and this verifies the efficacy of the proposed algorithm. [ABSTRACT FROM AUTHOR]

Published

2022

43. Improved Finite-Control-Set Model Predictive Control With Virtual Vectors for PMSHM Drives.

Author

Sun, Xiaodong, Li, Teng, Yao, Ming, Lei, Gang, Guo, Youguang, and Zhu, Jianguo

Subjects

COST functions, PREDICTION models, SYNCHRONOUS electric motors, VECTOR control, VOLTAGE references

Abstract

Finite-control-set model predictive current control (FCS-MPCC) always has large steady-state fluctuation and computational burden. In this paper, a novel FCS-MPCC without a modulator to drive permanent magnet synchronous hub motors (PMSHMs), which combines virtual vectors expansion scheme and duty cycle control was proposed. The lack of a modulator reduces the complexity of the control system. The virtual vectors are synthesized by using active vectors, which improve the accuracy of voltage selection, and further improve PMSHM's steady-state performance and reduce current harmonics. The duty cycle control uses a zero vector to obtain better steady-state performance. However, the duty cycle of the virtual vectors is limited by the synthesis method, and further analysis is needed. A new calculation process is proposed to reduce the amount of calculation. The deadbeat principle is used to get reference voltage which determines sectors. Then, the best voltage vector in the selected sector is determined by the predetermined cost function. The traditional MPCC and the duty cycle MPCC (DCMPCC) are used as a comparison item to compare with the proposed method to illustrate its effectiveness. Results confirm that improved MPCC has good steady-state performance while maintaining a fast dynamic response. [ABSTRACT FROM AUTHOR]

Published

2022

44. Position Sensorless Control of Switched Reluctance Motor Drives Based on a New Sliding Mode Observer Using Fourier Flux Linkage Model.

Author

Sun, Xiaodong, Tang, Xingtao, Tian, Xiang, Wu, Jiangling, and Zhu, Jianguo

Subjects

SWITCHED reluctance motors, MOTOR drives (Electric motors), SLIDING mode control, RELUCTANCE motors, DYNAMIC testing, SEPARATION of variables

Abstract

This paper proposes a new position sensorless method for switched reluctance motor (SRM) drive control based on a sliding mode observer using nonlinear Fourier flux linkage model. First, to obtain an accurate mathematical model of SRM for establishment of sliding mode position observer (SMPO), an analytical method based on Fourier polynomial function is introduced to regress the nonlinear relationship between flux linkage, position and current. Then, a new SMPO is designed in detail to estimate the rotor position, including the establishment of SRM model of sliding mode observer, and analysis of estimation error and convergence conditions of SMPO. Finally, position sensorless control of SRM drive based on SMPO is carried out in terms of accuracy and robustness in simulation. Experiments are also given on a dynamic testing platform to verify the effectiveness of the proposed position sensorless scheme. [ABSTRACT FROM AUTHOR]

Published

2022

45. Investigation of a 3D-Magnetic Flux PMSM With High Torque Density for Electric Vehicles.

Author

Chen, Hao, Demerdash, Nabeel A. O., EL-Refaie, Ayman M., Guo, Youguang, Hua, Wei, and Lee, Christopher H. T.

Subjects

ELECTRIC charge, ELECTRIC torque, PERMANENT magnet motors

Abstract

This paper presentsan investigation of a 3D-magnetic flux permanent magnet synchronous motor (3D-MF PMSM) used for electric vehicle applications. The investigated 3D-MF PMSM consists of an integrated radial-flux and axial-flux structure. It has two radial-flux air-gaps and two axial-flux air-gaps, as well as a toroidal winding wound stator. The integrated structure helps to concentrate all the flux within the motor to maximize torque production. Moreover, there are no end-windings in this motor and all the stator windings effectively are used in torque production. A comprehensive performance evaluation, in terms of the back-electromotive force, average output torque, cogging torque, torque ripple, flux-weakening capability, etc., of the investigated 3D-MF PMSM is conducted. An interior PMSM is purposely included as a benchmark for comparison. The results show that compared to the benchmark interior PMSM, the original 3D-MF PMSM exhibits significantly improved torque density, higher power factor, and higher efficiency, but suffers from serious cogging torque and torque ripple. Accordingly, a skewed arrangement is introduced to the 3D-MF PMSM. As a result, the cogging torque and torque ripple are significantly reduced. [ABSTRACT FROM AUTHOR]

Published

2022

46. Analytical Calculation of Air-Gap Magnetic Field in Brushless Doubly-Fed Reluctance Machine With Flux Barriers.

Author

Chen, Xi, Pan, Weidong, and Wang, Xuefan

Subjects

MAGNETIC fields, AIR gap flux, RELUCTANCE motors, ACTINIC flux, PERMANENT magnet motors, FINITE element method, MAGNETIC circuits

Abstract

This paper presents an analytical approach to determine the air-gap magnetic field and the winding inductance in the brushless doubly-fed reluctance machine (BDFRM) with flux barriers. By dividing one flux guide layer into several segments, a calculus method based on magnetic circuit analysis is developed and specific analytical expression of the air-gap flux density is rigorously derived. Then, the included angle between fundamental components with the same pole pairs is also discussed. Based on the air-gap flux density distribution, the inductance expressions between different windings are also presented. Three kinds of finite element analysis models are established and studied. As a result, the accuracy of the analytical model can be verified by simulations and experimental data from an existing BDFRM prototype. [ABSTRACT FROM AUTHOR]

Published

2022

47. Simplified Three-Vector-Based Model Predictive Direct Power Control for Dual Three-Phase PMSG.

Author

Ji, Jinghua, Jin, Shibo, Zhao, Wenxiang, Xu, Dezhi, Huang, Linsen, and Qiu, Xianqun

Subjects

PREDICTION models, REACTIVE power, PREDICTIVE control systems, SYNCHRONOUS generators

Abstract

The conventional model predictive power control suffers from heavy computational burden and large power ripple. To address the problem, this paper proposes a simplified three-vector-based model predictive direct power control, which can greatly optimize the control set. Firstly, a switching table is designed to exclude the redundant virtual voltage vectors (VVs). Only half of the candidate VVs are retained. Then, the effect of each VV on power is analyzed in detail. The deviation of reactive power is used as the evidence to further simplify the control set. In this way, the prediction behavior is reduced from 12 to 2, which effectively reduces the computational burden. In addition, the concept of power deadbeat is employed to determine the duty cycles of the two virtual VVs and one zero VV. Thus, the power ripples and current harmonics can be considerably suppressed. With this proposed method, the calculation complexity is reduced, and the steady-state performance is improved. The simulation and experimental results are given to verify the proposed method. [ABSTRACT FROM AUTHOR]

Published

2022

48. A Novel Quasi-3D Analytical Model for Axial Flux Motors Considering Magnetic Saturation.

Author

Zhao, Hang, Chau, K. T., Yang, Tengbo, Song, Zaixin, and Liu, Chunhua

Subjects

CARTESIAN coordinates, PARTIAL differential equations, FINITE element method, MAGNETIC fields

Abstract

The magnetic field calculation for axial flux motors (AFMs) is always intricate and time-consuming. To this end, a fast quasi-three-dimensional (3D) analytical model is proposed in this paper for magnetic field prediction in AFMs. The 3D magnetic field problem can be simplified into a two-dimensional (2D) one by dividing the AFM into several annular slices in the radial direction. Then, for the first time, the harmonic modeling method (HMM) in Cartesian coordinates is adopted to solve the magnetic field in these slices cut from the AFM. The corresponding electromagnetic parameters of the AFM can be acquired subsequently. The critical step for the field prediction of using HMM in Cartesian coordinates is to adopt a variable substitution method when solving the partial differential equations. Next, the magnetic saturation of soft-magnetic material within AFMs is considered by adopting an iterative approach. Ultimately, the effectiveness of the proposed quasi-3D analytical model is validated by the nonlinear finite element analysis (FEA). The proposed analytical model is computationally efficient, which makes it suitable for the preliminary design of AFMs. [ABSTRACT FROM AUTHOR]

Published

2022

49. Investigation of Multi-Layer Secondary Concept of an Electromagnetic Launcher.

Author

Samimi, Morteza and Hassannia, Amir

Subjects

ELECTROMAGNETIC launchers, FINITE element method, LINEAR induction motors, TERMINAL velocity

Abstract

Electromagnetic launchers are somewhat preferred to combustion and mechanical ones due to their superior advantages. Acceleration improvement in a limited motor length is the major problem of these machines. Optimal shape of secondary sheet has the great importance on launching procedure, which is investigated in this paper. The common methods of acceleration improvement have been explored on a 4 kW, 600 mm case-studied launcher. Multi-layer secondary is then proposed and investigated on case-studied machine. The efficacy of proposed topology is verified by finite elements method (FEM) as well as experimental tests. [ABSTRACT FROM AUTHOR]

Published

2022

50. Model Predictive Direct Torque Control of Switched Reluctance Motors for Low-Speed Operation.

Author

Li, Wei, Cui, Zhiwei, Ding, Shichuan, Chen, Fan, and Guo, Yiyang

Subjects

TORQUE control, SWITCHED reluctance motors, COST functions, PREDICTION models, TORQUE, VOLTAGE control

Abstract

In this paper, a finite-control-set model predictive direct torque control (FCS-MPDTC) method is proposed to reduce the torque ripple of a segmented switched reluctance motor (SSRM) at the low-speed stage. Firstly, the prediction dynamic model is established, and the phase torque can be predicted by detecting phase current and rotor position signals. Then, the principle of power converter and selection of voltage vectors are introduced and presented. Considering torque ripple reduction, flux tracking performance and copper losses reduction, the cost function with phase torque, the amplitude of flux linkage and phase current, is established to select optimal voltage vector to control the power converter. In addition, the torque sharing function (TSF) is employed to distribute total torque to phase torque for further torque ripple reduction. Finally, the direct torque control (DTC) is selected as the comparison method, performance of MPDTC is verified by simulation and experiment results. It can be found that the proposed MPDTC can achieve lower torque ripple and copper losses, and high robustness. [ABSTRACT FROM AUTHOR]

Published

2022