The electric vehicle market is rapidly evolving, with two- and three-wheeled vehicles gaining popularity for good reason. From e-scooters and e-mopeds to e-rickshaws, these vehicles provide the cost-effectiveness, efficiency, and sustainability consumers want.
According to a Deloitte-ThoughtLab Global City Survey, eco-friendly consumer transportation — particularly e-scooters and e-bikes — is a key focus area for municipalities transforming into smart cities.
Electric two-wheelers (E2Ws) and electric three-wheelers (E3Ws) have a wide appeal for several reasons, including:
There are several considerations engineers should address when developing the electrical systems that power E2Ws and E3Ws:
Effective power management is crucial, so choosing the appropriate battery size, type, power density, and charging infrastructure is imperative. Because the battery management system (BMS) plays a vital role in safety and performance, consider including advanced features, including state-of-charge estimation, cell balancing, and fault diagnostics.
Motor selection dramatically impacts performance, so carefully weigh the pros and cons of using a hub motor vs. a mid-drive motor for optimal cost, climbing ability, efficiency, and weight distribution. Brushless DC (BLDC) motors are often a popular choice due to their high efficiency, reliability, and compact size.
A robust motor controller is crucial for reliable power delivery to the motor. Precise torque control, smooth acceleration, and regenerative braking capabilities can optimize operation.
Electrical architecture and wiring play a vital role in reliability. Use the centralized or distributed electrical system best suited for the application, complexity, and budget. All wiring should be lightweight and protected from environmental factors. Select the right communication protocol for communication between different electronic control units for reliable data exchange.
Adequate measures should be implemented to prevent damage from overcurrent and overvoltage, as well as functional features such as redundant systems to improve the overall safety of the vehicle.
Optimize the rider experience with simplified vehicle controls and an intuitive user interface.
Appropriate heat dissipation strategies should be implemented to maintain battery performance and lifespan, as well as overall operation. Features like heatsinks, packages with exceptional thermal properties like MCC’s dual-side cooling MOSFETs, and PCB layout design could impact thermal performance.
Design for convenient access to charging ports and compatibility with various charging methods, including home charging, fast charging, or battery swapping. Consider implementing a smart charging system that also optimizes rates and battery health.
To enhance the user experience, consider telematics for GPS tracking and remote diagnostics, or mobile app integration for easy access to battery status updates. For ride-sharing or fleet management, features such as Bluetooth and cellular capabilities benefit users.
Conduct rigorous testing to ensure reliability and compliance with stringent industry standards as well as applicable safety and emissions regulations.
MCC is committed to delivering high-quality semiconductors suited for the unique needs and challenges of two- and three-wheeled EVs through:
This shift to urban mobility and sustainability is sure to evolve, generating demand for advanced semiconductor solutions to support growth in the two- and three-wheeled EV sector.
Whether it’s a MOSFET for a battery management system or motor control, MCC is well-positioned to support current and changing needs through unmatched service and commitment.
Contact our team for assistance with part selection or to request engineering samples.