On the Use of Vibration Synthesis to Ease Electric Machine Powertrain Design

2020 International Conference on Electrical Machines (ICEM)

Chauvicourt

Varaticeanu

et al. 2020

Electrical machine electromagnetic-caused noise and vibration represents an ever-increasing target for machinedesigners. A novel late design-stage NVH optimization method using the full rotational velocity synthesized vibration-response map is proposed. This is assisted by a target-setting method for the most important force harmonics using a force sensitivity analysis. The procedure is applied on a PMASynRM used for light traction applications, where the rotor cross-section is modified by introducing notches and saliency. The results for different percentages of permitted decrease in average show that both resonances and individual frequency orders can be directly targeted and minimized.

Section: A Structural Dynamics Analysis Using Vibration Synthesismentioning

confidence: 99%

PMASynRM late design-stage rotor shape NVH optimization

2020 International Conference on Electrical Machines (ICEM)

Chauvicourt

Varaticeanu

et al. 2020

“…The vibration synthesis uses the superposition of dynamics responses for each important excitation force shape component [2]. This is achieved by using a modal frequency response solution, where the excitation F [I],shape is a unitary force shape with energy conservation properties -the total energy per frequency line equal to 1 N [13]:…”

Section: B Vibration Synthesismentioning

confidence: 99%

PMASynRM system-level NVH model with eccentricity

2020 IEEE Transportation Electrification Conference &Amp; Expo (ITEC)

Chauvicourt

Martis

2020

This paper presents a high-fidelity system-level vibration model for a permanent-magnet assisted synchronous reluctance machine that is able to capture static and dynamic eccentricity effects. The procedure of extracting finite-element data from a series of magnetostaic analyses that include rotor displacement is presented. Afterwards, the flux-linkage state variable system-level model that uses the previous data is developed. Subsequently, the vibration-synthesis method that includes the additional time and space eccentricity-induced force harmonics is discussed and vibration response of the systemlevel model is presented and compared to the non-eccentric case. Additionally, the effect of different eccentricity orbits on the unbalance magnetic pull force is exemplified.

“…Fourier series decomposition is applied to the radial force to isolate the spatial and the rotor position dependent components. This procedure allows to simplify the analysis within SL model simulation and it is performed for each operating point following [3], [8]:…”

Section: A System-level Modelmentioning

confidence: 99%

“…This, essentially results from the multi-physical characteristic of noise and vibrations (control, structural dynamics, electromagnetics). Previous work on the SL simulation approaches can be found on [2], [3].…”

Section: Introductionmentioning

confidence: 99%

Comparative study between PMSM models used for NVH system-level simulation

Sarrio

2019 Electric Vehicles International Conference (EV)

Marțiș

et al. 2019

Modeling of automotive Permanent MagnetSynchronous Machines (PMSM) electric drives for Noise, Vibration and Harshness (NVH) assessment involves modeling different components such as electrical machine, power electronics and controller. The usage of transistors for machine control affects the NVH performance, especially within the switching frequency range. Traditionally the method to include power electronics models is to use co-simulation to couple a circuit simulator with an electromagnetic Finite Element (FE) model. However, this approach is computationally expensive. To overcome this limitation, the electromagnetic behavior of the machine can be approximated by using reduced order models. This work compares the co-simulation approach with the system-level model in terms of high frequency NHV behavior. The comparison provides results in terms of time and accuracy.