Your search keyword '"Ahmed, Shehab"' showing total 12 results

1. A Nine-Phase Six-Terminal Concentrated Single-Layer Winding Layout for High-Power Medium-Voltage Induction Machines.

Author

Abdel-Khalik, Ayman S., Ahmed, Shehab, and Massoud, Ahmed M.

Subjects

*ELECTRIC windings, *INDUCTION machinery, *VOLTAGE-frequency converters, *FINITE element method, *TORQUE

Abstract

This paper proposes a new winding layout for high-power medium-voltage nine-phase induction machines (IMs) based on a single-layer concentrated winding layout having a unity winding factor. The machine is fundamentally an asymmetrical nine-phase IM, where phases are connected in such a way as to provide six terminals that are fed from two three-phase inverters. Compared to a conventional asymmetrical six-phase IM with the same stator and copper volumes, it provides improved torque density, a higher torque/current ratio, and a simpler winding layout. Finite-element simulation is used to compare the proposed winding layout with a conventional split-phase six-phase IM to assess the claimed merits. A 1.5-hp prototype IM is also used for experimental verification. The experimental results are given under both healthy and fault conditions, where the faulty converter is completely disabled. The achievable derating factors under this case are then given and compared with those of conventional six-phase IMs. [ABSTRACT FROM PUBLISHER]

Published

2017

2. Steady-State Mathematical Modeling of a Five-Phase Induction Machine With a Combined Star/Pentagon Stator Winding Connection.

Author

Abdel-Khalik, Ayman S., Ahmed, Shehab, and Massoud, Ahmed M.

Subjects

*ELECTROMAGNETIC induction, *ELECTROSTATIC induction, *VECTOR analysis, *MATHEMATICAL models, *MATHEMATICAL decomposition

Abstract

This paper presents the steady-state mathematical model of a five-phase induction machine with a combined star/pentagon connection. The connection splits the stator winding into two five-phase windings displaced in space by $\pi$/10 and connected in a combined star/pentagon configuration. Recent work limited to an experimental investigation demonstrated that the connection possesses improved fault tolerance when compared to a conventional star-connected stator, as well as avoids the pentagon connection problems. Although the machine has five-phase terminals, it is intrinsically an asymmetrical ten-phase machine, which introduces additional subspaces in the machine's mathematical model. In order to theoretically investigate and thoroughly assess this connection against conventional connections, this paper introduces the steady-state mathematical model based on vector space decomposition and symmetrical component theory. Finite-element analysis is first used to investigate the different harmonic current components induced in the cage rotor circuit, upon which the effect of different subspaces can be clarified and the required transformation matrix from phase variables to their sequence components can be derived. The model is verified using a 1-kW prototype five-phase induction machine. [ABSTRACT FROM PUBLISHER]

Published

2016

3. Performance Evaluation of a Five-Phase Modular Winding Induction Machine.

Author

Abdel-Khalik, Ayman S. and Ahmed, Shehab

Subjects

*WINDING machines, *PERMANENT magnet motors, *INDUCTION machinery, *SUBMERSIBLE pumps, *TORQUE, *SIMULATION methods & models

Abstract

Fractional slot concentrated windings (FSCWs), or modular windings, have shown promise with permanent magnet machines. However, their inability to produce high quality travelling fields has limited their application from spreading to induction machines. This paper presents the design considerations and tradeoffs involved in applying FSCWs to five-phase induction machines using the conventional three-phase lap wound machine as a reference. Previous work has touched upon the application of modular windings to three-phase induction machines, concluding that a conventional distributed winding is superior in terms of torque production and rotor bar losses. In applications such as high frequency induction machines and manually wound electrical submersible pump motors, the proposed machine topology provides advantages that may warrant its application despite an apparent power density penalty. In this paper, a prototype five-phase modular winding induction machine designed to significantly reduce the effect of space harmonics is investigated through simulations and experimentally. [ABSTRACT FROM PUBLISHER]

Published

2012

4. An Improved Torque Density Pseudo Six-Phase Induction Machine Using a Quadruple Three-Phase Stator Winding.

Author

Abdel-Khalik, Ayman S., Massoud, Ahmed M., and Ahmed, Shehab

Subjects

*INDUCTION machinery, *STATORS, *PERMANENT magnet generators, *MACHINING, *TORQUE, *WINDING machines, *DENSITY

Abstract

The nine-phase six-terminal induction machine has recently been proposed as a promising contender to the conventional six-phase asymmetrical winding machine in terms of torque density, phase current quality, stator winding simplicity, and fault-tolerant capability. However, the relatively lower dc-link voltage utilization of a single neutral arrangement in multiphase machines with multiple three-phase windings represents, in general, a technical challenge when compared to windings with isolated star points. Therefore, this paper proposes a new pseudo six-phase winding layout suitable for medium-voltage high-power induction machines, which employs quadruple three-phase stator winding sets, while providing the same terminal behavior of a nine-phase six-terminal winding. Additionally, like the traditional six-phase winding, two possible neutral arrangements can be configured. The proposed winding configuration provides the same dc-link voltage utilization as in conventional dual three-phase winding machines with isolated neutrals. The effect of the circulating zero-sequence current component experienced with a single neutral arrangement can also be avoided. A 1.5 Hp prototype induction machine is used to experimentally validate the proposed six-phase winding layout under both healthy and fault conditions. [ABSTRACT FROM AUTHOR]

Published

2020

5. Application of Standard Three-Phase Stator Frames in Prime Phase Order Multiphase Machine Construction.

Author

Abdel-Khalik, Ayman S., Massoud, Ahmed M., and Ahmed, Shehab

Subjects

*STATORS, *INDUCTION machinery, *PRIME numbers, *FINITE element method, *THREE-phase alternating currents

Abstract

The application of multiphase machines in high-power applications is now a recognized alternative, thanks to their higher fault-tolerance when compared with standard three-phase systems. Although multiphase machines with multiples of three-phase winding sets have been favored in many applications, literature has shown that machines with a prime number of phases, such as five-phase machines, generally outperform other phase orders, especially in terms of machine torque density. One of the major problems when dealing with a prime number of phases either in academic research or industrial applications is the special stator design. This paper provides a general technique to rewind standard off-the-shelf three-phase stator frames with any general prime phase order while preserving the same copper volume. The proposed winding layout is derived using the star of slots theory and the concept of stator winding shifting. Finite-element simulations are used to investigate examples with different phase orders, while experimental investigation is carried out to corroborate the proposed concept by rewinding a standard three-phase stator as a five-phase machine. [ABSTRACT FROM AUTHOR]

Published

2019

6. Nine-Phase Six-Terminal Induction Machine Modeling Using Vector Space Decomposition.

Author

Abdel-Khalik, Ayman S., Massoud, Ahmed M., and Ahmed, Shehab

Subjects

*VECTOR spaces, *INDUCTION machinery, *SUBSPACE identification (Mathematics), *SUBSPACES (Mathematics), *ELECTRIC inverters

Abstract

The nine-phase six-terminal induction machine (IM) has been recently proposed as a promising contender to the conventional asymmetrical six-phase type in terms of torque density, stator winding simplicity, and fault-tolerant capability. The stator is composed of nine phases, which are connected in a fashion to only provide six stator terminals. Therefore, this connection combines the high performance of a nine-phase winding with the terminal behavior of a six-phase machine. This paper introduces the machine mathematical model based on the vector space decomposition (VSD) modeling approach. The required current and voltage sequence transformation matrices are derived such that the machine is mathematically regarded as an equivalent six-phase IM with only three decoupled subspaces. This way, the same VSD-based controller structures conventionally applied to six-phase-based systems can be preserved. A 1.5-hp prototype IM is used to experimentally validate the machine model under both healthy and open-phase conditions. [ABSTRACT FROM AUTHOR]

Published

2019

7. An Improved Fault-Tolerant Five-Phase Induction Machine Using a Combined Star/Pentagon Single Layer Stator Winding Connection.

Author

Abdel-Khalik, Ayman S., Elgenedy, Mohamed A., Ahmed, Shehab, and Massoud, Ahmed M.

Subjects

*PERFORMANCE of induction motors, *INDUCTION motor efficiency, *STATORS, *WINDING machines, *PROTOTYPES

Abstract

One of the main merits offered by multiphase machines is their high fault-tolerant capability. Literature has demonstrated that the performance of multiphase induction machines under fault conditions is affected by the employed stator winding connection. In open-loop controlled five-phase machines, the star connection is favorable under healthy conditions while the pentagon connection is favorable and yields a lower derating factor under the open phase condition. In this paper, a new combined star/pentagon single layer winding layout that combines the advantages of both star and pentagon connections is proposed for a five-phase induction machine. Although the proposed winding is intrinsically an asymmetrical ten-phase machine, the proposed connection allows for only five-phase terminals. Moreover, the proposed winding not only yields better flux distribution compared to a conventional single layer winding, but also provides a complete cancellation of the third-order harmonic flux component caused by the induced third sequence currents due to the saturation effect and/or under unbalanced operation. Hence, the machine losses are decreased, which improves the overall machine efficiency. For the healthy case, the machine is similar to a conventional star connected five-phase machine. However, with one phase open, the proposed connection results in a lower derating factor compared to conventional connections for both open-loop and optimal current control techniques. A 1-kW prototype machine is used for experimental verification. [ABSTRACT FROM AUTHOR]

Published

2016

8. Parameter Identification of Five-Phase Induction Machines With Single Layer Windings.

Author

Abdel-Khalik, Ayman S., Daoud, Mohamed I., Ahmed, Shehab, Elserougi, Ahmed A., and Massoud, Ahmed M.

Subjects

*INDUCTION machinery, *PARAMETER identification, *ELECTRIC inductance, *STATORS, *WINDING machines

Abstract

Despite the increased interest in multiphase induction machines for safety-critical applications, machine parameter identification for the different sequence planes is still a challenging research point. In most available literature, the effect of nonfundamental sequence planes is overlooked due to the assumption of sinusoidal winding distribution and healthy operation. However, in a single layer or concentric winding layout with an odd number of phases, the effect of flux produced by nonfundamental sequence planes cannot be ignored for the open-phase case. This paper proposes a simple offline method to estimate the parameters of a five-phase induction machine corresponding to different sequence planes. The proposed technique can estimate the stator leakage inductance as well as the magnetizing inductance of both fundamental and third sequences by applying a quasi-square voltage to the stator winding while the machine is running at no-load. Consequently, the rotor circuit parameters of the fundamental sequence plane can be simply obtained by deducting the stator impedance from the blocked rotor machine impedance. For the third sequence plane, an approximate relation to estimate these parameters based on the measured fundamental sequence rotor parameters is also given. An experimental 1.5 Hp prototype machine is used to verify the proposed technique. [ABSTRACT FROM PUBLISHER]

Published

2014

9. Effect of Stator Winding Connection on Performance of Five-Phase Induction Machines.

Author

Abdel-Khalik, Ayman S., Morsy, Ahmed S., Ahmed, Shehab, and Massoud, Ahmed M.

Subjects

*STATORS, *ELECTRIC windings, *INDUCTION machinery, *ELECTRIC connectors, *FAULT currents, *ELECTRIC controllers

Abstract

This paper studies the effect of stator winding configuration on the performance of five-phase induction machines under healthy as well as faulty conditions. The study compares two connections, namely, star and pentagon connections. The comparison is conducted using both simulation and experimental results. The steady-state model based on symmetrical components theory is introduced for both connections with one-line open due to a converter fault, and the corresponding machine characteristic curves are estimated. During faults, two alternatives for machine operation are possible, namely, open-loop control and optimal current control. While the first alternative corresponds to higher torque ripple and unbalanced winding currents, the second option necessitates unbalanced phase voltages and typically an increased dc-link voltage to source the required optimal currents. Consequently, an increase in the employed semiconductor device rating is required, which is a critical design factor particularly in medium-voltage applications. A new V/f control technique is proposed to ensure disturbance-free operation with one-line open for both winding connections. Based on the unbalanced machine model and experimental verification, the derating factors that ensure safe machine operation for both winding connection alternatives are calculated. The comparison between the two connections shows the superiority of the pentagon connection under fault conditions in terms of efficiency, average torque, torque ripples, and derating factor. [ABSTRACT FROM PUBLISHER]

Published

2014

10. Postfault Operation of Onboard Integrated Battery Charger via a Nine-Phase EV-Drive Train.

Author

Abdel-Majeed, Mahmoud S., Eldeeb, Hisham M., Metwly, Mohamed Y., Abdel-Khalik, Ayman S., Hamad, Mostafa S., Hamdy, Ragi A., and Ahmed, Shehab

Subjects

*BATTERY chargers, *TORQUE, *ROTORS

Abstract

This article presents the operation of onboard integrated battery chargers tied to a nine-phase EV-drive train, shedding light on the charging performance during the postfault operation, when one or more faulty inverter legs are disconnected. The objective in that case is to ensure balanced grid currents, while maintaining minimum machine losses at zero average torque production. The proposed concept requires a minimalistic change from a control structure perspective to switch between the pre- and postfault cases. Limitations and fault cases are discussed and corroborated with experimental tests on a 1.5-kW prototype.The derived concept is parameter independent and applicable to nine-phase drives, irrespective of the type of rotor used. [ABSTRACT FROM AUTHOR]

Published

2021

11. Postfault Operation of a Nine-Phase Six-Terminal Induction Machine Under Single Open-Line Fault.

Author

Abdel-Khalik, Ayman Samy, Hamad, Mostafa S., Massoud, Ahmed M., and Ahmed, Shehab

Subjects

*FAULT tolerance (Engineering), *INDUCTION machinery, *STATORS, *ELECTRIC windings, *INDUCTION motors, *TORQUE measurements

Abstract

This paper studies the postfault control of a nine-phase six-terminal induction machine (IM) during single open-line fault, which was recently proposed for high-power medium-voltage applications as a promising alternative to conventional six-phase IMs. The required optimal reference currents to provide prefault loading conditions under one-line open are derived using the two most common optimization criteria employed in multiphase drives, namely, maximum torque and minimum loss modes. A postfault controller, based on conventional decoupling Clarke's transformation, is then used to ensure the same controller structure under all conditions. Consequently, the machine characteristic curves, achievable torque, and stator copper losses under these different modes are compared. A comparison with a conventional asymmetrical six-phase winding is also given. A 1.5-Hp prototype IM is used for experimental verification. [ABSTRACT FROM PUBLISHER]

Published

2018

12. A Nine-Switch-Converter-Based Integrated Motor Drive and Battery Charger System for EVs Using Symmetrical Six-Phase Machines.

Author

Diab, Mohamed S., Elserougi, Ahmed A., Abdel-Khalik, Ayman S., Massoud, Ahmed M., and Ahmed, Shehab

Subjects

*PULSE width modulation transformers, *ELECTRIC vehicle batteries, *BATTERY chargers, *ELECTRIC batteries, *CONVERTERS (Electronics)

Abstract

This paper presents a new configuration for integrated on-board battery chargers of electric vehicles (EVs) incorporating symmetrical six-phase machines. The configuration proposes an exclusive utilization of a nine-switch converter (NSC) along with the machine windings during both propulsion and charging of EVs. The proposed configuration has the advantage of employing a reduced number of components in both the EV (on-board) and charging station (off-board), with the privilege of avoiding machine electromagnetic torque production during charging/vehicle-to-grid (V2G) mode of operation. During charging/V2G mode, the NSC is turned into a conventional three-phase pulse width modulation rectifier and is directly connected to the three-phase mains through the machine windings. Conventional three-phase transformers can be employed for galvanic isolation. Switching between propulsion and charging modes is carried out using a simple hardware reconfiguration. Control schemes for both propulsion and charging/V2G modes are elaborated, along with the principles of operation of the NSC. Experimental results are provided to validate the theoretical deductions for the different operating modes. [ABSTRACT FROM PUBLISHER]

Published

2016