Course level:Intermediate

Certification Course in Motor & Drive System for EVs: Design & Optimization

“The Certification Course in Motor & Drive Systems for Electric Vehicles: Design & Optimization” offers a deep dive into the design, optimization, and control of electric motors and their drive systems for electric vehicles (EVs). This course covers fundamental motor principles, power electronics, DC and AC motor drives, inverter-fed drives, and advanced control techniques, focusing on real-world EV applications. Through hands-on simulations, participants will acquire the skills needed to design, optimize, and test electric motor systems for EV powertrains.

At a glance

  • 10 Modules
  • 61 Lectures
  • 18.80 Hours of video content.
  • 1 Project Assignment
  • Certification of Completion.
$1,500.00
  • Level
    Intermediate
  • Duration
    18 hours 49 minutes
  • Enrollment validity
    Enrollment validity: Lifetime
  • Certificate
    Certificate of completion

Course Curriculum

Welcome to the Course!

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Module 1: Fundamentals of Electric Motors
This module introduces the core principles of electric motors, including torque production, magnetic circuits, and energy conversion. Students will explore motor output characteristics, specific loadings, and the general properties of electric motors, with an emphasis on safety standards relevant to the EV industry.

Module 2: Power Electronics for Motor Drives
In this module, participants will learn about the power electronics that control motor drives. Topics include voltage control techniques, DC/AC conversion, inversion techniques, and inverter switching devices. The module also covers converter waveforms, acoustic noise control, and the cooling of power switching devices.

Module 3: Conventional DC Motors and Drives
This module covers the operating principles of conventional DC motors, including torque production and motional EMF. Participants will study the steady-state and transient performance characteristics, four-quadrant operation, regenerative braking, and various types of DC drives such as thyristor, chopper-fed, and digitally controlled drives.

Module 4: Induction Motors and Drives
Focused on induction motors, this module covers the basics of rotating magnetic fields and torque production. Students will explore stator current-speed characteristics, torque-speed curves, rotor parameters, speed control methods, and power factor control.

Module 5: Induction Motor Equivalent Circuits
Participants will study the similarity between induction motors and transformers, learning how to develop an equivalent circuit for an induction motor. This module covers properties of induction motors, performance prediction, and the impact of variable frequency conditions on motor performance.

Module 6: Inverter-Fed and Advanced Induction Motor Drives
This module delves into the torque-speed characteristics of inverter-fed induction motors. Students will explore control arrangements for inverter-fed drives, including vector (field-oriented) control and cycloconverter drives, which are critical for high-performance EV applications.

Module 7: Stepping Motors
Participants will learn the principles of stepping motor operation, including steady-state and transient performance characteristics. The module covers ideal (constant-current) drive circuits and the analysis of pull-out torque-speed curves.

Module 8: Synchronous, Brushless DC, and Switched Reluctance Drives
This module provides an overview of synchronous motors, brushless DC motors, and switched reluctance motor drives. Focus is placed on controlled-speed drives, highlighting their application in EV powertrains.

Module 9: Motor and Drive Selection
In this module, participants will learn how to select the appropriate motor and drive system for various EV applications. Topics include power range considerations, torque-speed characteristics, and general application guidelines to meet load requirements.

Module 10: Advanced Motor Technology and Control for Powertrain
This advanced module focuses on electric motor design principles specifically for EVs, covering high-performance materials and control techniques. Participants will explore electric motor testing, characterization, integration into powertrains, and noise, vibration, and harshness (NVH) analysis. Additionally, the module covers reliability and lifetime analysis of electric motors, crucial for long-term performance in EV applications.

DIY Projects:

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Associated Skills

Advanced Motor Control for EVs Brushless DC Motors DC Motors and Drives Electric Motors Fundamentals Induction Motor Control Inverter-Fed Drives Magnetic Circuits Motor Selection and Drive Integration Power Electronics for Motor Drives Stepping Motors Synchronous Motors Torque Production

DIY Projects Included

Course Benefits

Technical expertise you will gain

Who can take this course?

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At a glance

  • 10 Modules
  • 61 Lectures
  • 18.80 Hours of video content.
  • 1 Project Assignment
  • Certification of Completion.
$1,500.00
  • Level
    Intermediate
  • Duration
    18 hours 49 minutes
  • Enrollment validity
    Enrollment validity: Lifetime
  • Certificate
    Certificate of completion

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