Your search keyword '"Nehl, Thomas"' showing total 3 results

1. Design Optimization of an Electric Machine for a 48-V Hybrid Vehicle With Comparison of Rotor Technologies and Pole-Slot Combinations.

Author

Fatemi, Alireza, Nehl, Thomas W., Yang, Xiaofeng, Hao, Lei, Gopalakrishnan, Suresh, Omekanda, Avoki M., and Namuduri, Chandra S.

Subjects

*ELECTRIC machines, *HYBRID electric cars, *COMPUTATIONAL fluid dynamics, *ROTORS, *DEMAGNETIZATION

Abstract

Through analytical equations followed by a systematic optimization study using high-fidelity finite-element (FE) models, the torque capability of three common synchronous machine technologies—namely, a permanent magnet (PM) synchronous machine (PMSM) with V-shaped rare-earth rotor magnets, a PMSM with deep V-shaped ferrite rotor magnets, and a synchronous reluctance machine (SynRM) with four layers of conforming flux barriers are compared for an application in a 48-V mild hybrid electric car. The optimization of the deep V-shaped ferrite PMSM automatically resulted in a spoke-type PM layout for maximum torque production. Yet, an optimized SynRM with conforming flux barriers was achieved that could produce a higher torque than ferrite PMSM. One machine technology is selected and six variants of it, with two rotor PM layouts each with three alternative pole-slot combinations, are subsequently subjected to a large-scale FE model-based drive-cycle design optimization. Various pole-slot combinations are methodically compared in terms of drive-cycle losses, active material cost, torque ripple, and PM demagnetization level. More than 20 000 designs were analyzed over ten energy-centric torque-speed points to identify an optimal design solution. The results of multiphysics analysis incorporating electromagnetics, computational fluid dynamics, and structural analyses are provided, including a study on three different water jacket concepts. A final design is prototyped and primary experimental results are provided. [ABSTRACT FROM AUTHOR]

Published

2020

2. PM-Assisted Synchronous Reluctance Machine Drive System for Micro-Hybrid Application.

Author

Hao, Lei, Namuduri, Chandra S., Gopalakrishnan, Suresh, Mavuru, Chandra Mouli, Atluri, Prasad, and Nehl, Thomas W.

Subjects

RELUCTANCE motors, REGENERATIVE braking, ENERGY consumption, POWER resources, MACHINING, ALTERNATING current generators, SYNCHRONOUS electric motors

Abstract

The demand for increased power and improved fuel economy are driving changes in alternator technology for automotive applications. To meet these demands requires a drive system with capabilities of torque assist, regenerative braking and power generation to supply vehicle loads while keeping the battery charged. Furthermore, to minimize add-on cost, the system must be air-cooled with minimal changes to the vehicle hardware and operate at 12 V with the same or smaller packaging footprint of the current alternator. In this paper, a low cost 12 V, 4 kW air-cooled permanent magnet-assisted synchronous reluctance machine drive system for a micro-hybrid vehicle is presented. The design and analysis in terms of machine, inverter, controller, and control algorithm are discussed in detail. Thermal performance of the system under different operating conditions, which is another key aspect for the harsh environment application, is also studied. Fuel economy analysis of the proposed low-cost micro-hybrid system for a Segment B vehicle shows significant reduction in fuel consumption resulting in a direct benefit to the customer. Finally, a prototype drive system was built and tested and found to meet the cost, performance, and packaging requirements. [ABSTRACT FROM AUTHOR]

Published

2019

3. Optimal Design of IPM Motors With Different Cooling Systems and Winding Configurations.

Author

Fatemi, Alireza, Ionel, Dan M., Demerdash, Nabeel A. O., and Nehl, Thomas W.

Subjects

PERMANENT magnet motors, MATHEMATICAL optimization, AMPERES, MAGNETIC cores, FINITE element method

Abstract

Performance improvement of permanent magnet (PM) motors through optimization techniques has been widely investigated in the literature. Oftentimes the practice of design optimization leads to derivation/interpretation of optimal scaling rules of PM motors for a particular loading condition. This paper demonstrates how these derivations vary with respect to the machine ampere loading and ferrous core saturation level. A parallel sensitivity analysis using a second-order response surface methodology followed by a large-scale design optimization based on evolutionary algorithms are pursued in order to establish the variation of the relationships between the main design parameters and the performance characteristics with respect to the ampere loading and magnetic core saturation levels prevalent in the naturally cooled, fan-cooled, and liquid-cooled machines. For this purpose, a finite-element-based platform with a full account of complex geometry, magnetic core nonlinearities, and stator and rotor losses is used. Four main performance metrics including active material cost, power losses, torque ripple, and rotor PM demagnetization are investigated for two generic industrial PM motors with distributed and concentrated windings with subsequent conclusions drawn based on the results. [ABSTRACT FROM PUBLISHER]

Published

2016