ELECTRIFIED VEHICLE

Organization Name

HYUNDAI MOTOR COMPANY

Inventor(s)

Young Jin Jang of Seoul (KR)

ELECTRIFIED VEHICLE - A simplified explanation of the abstract

This abstract first appeared for US patent application 18099453 titled 'ELECTRIFIED VEHICLE

The abstract describes an electrified vehicle with a motor, a power factor correction circuit, and a DC/DC converter for efficient power management.

• The vehicle includes a motor with windings and a power factor correction circuit with AC and DC terminals.
• The power factor correction circuit has legs corresponding to the AC terminals and is connected between the DC terminals.
• The DC/DC converter has a first switching circuit connected to the battery terminals and a second switching circuit connected to the DC terminals.
• The converter switches between different legs to output the battery voltage to the motor or the DC terminals via a transformer.
• In battery discharging mode, the converter switches the primary and secondary legs to output the battery voltage to the DC terminals.
• When the motor is driven, the converter switches the primary legs to output the battery voltage to the motor.

Potential Applications: - Electric vehicles - Hybrid vehicles - Renewable energy systems

Problems Solved: - Efficient power management in electrified vehicles - Improved motor performance - Enhanced energy conversion

Benefits: - Increased energy efficiency - Extended battery life - Reduced emissions

Commercial Applications: - Electric vehicle manufacturers - Renewable energy companies - Power electronics industry

Questions about the technology: 1. How does the power factor correction circuit improve energy efficiency? 2. What are the key advantages of using a DC/DC converter in electrified vehicles?

Original Abstract Submitted

An electrified vehicle includes a motor including windings, a power factor correction circuit including AC and DC terminals and including legs corresponding to respective AC terminals and connected between the DC terminals, and a DC/DC converter including a first switching circuit including first, second, and third primary legs connected between terminals of a battery, a second switching circuit including at least one secondary leg connected between the DC terminals, and a transformer connected between the first and second switching circuits. In a battery discharging mode, the DC/DC converter switches the first primary leg and the at least one secondary leg, outputting a voltage of the battery to the DC terminals via the transformer. When the motor may be driven, the DC/DC converter switches the second and third primary legs electrically disconnected from the transformer, outputting the voltage of the battery to the motor.