SYSTEMS AND METHODS FOR DECOUPLING CAPACITOR FOR INVERTER FOR ELECTRIC VEHICLE

Organization Name

delphi technologies ip limited

Inventor(s)

Seyed R. Zarabadi of Kokomo IN (US)

Mark Wendell Gose of Kokomo IN (US)

David Paul Buehler of Noblesville IN (US)

SYSTEMS AND METHODS FOR DECOUPLING CAPACITOR FOR INVERTER FOR ELECTRIC VEHICLE - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240106371 titled 'SYSTEMS AND METHODS FOR DECOUPLING CAPACITOR FOR INVERTER FOR ELECTRIC VEHICLE

Simplified Explanation

The system described in the abstract is a power inverter that converts DC power from a battery into AC power to drive a motor. The inverter includes a first decoupling capacitor and a first power module with upper and lower phase switches to control the flow of current between the battery and the motor.

• The inverter converts DC power from a battery to AC power for a motor.
• The first decoupling capacitor is connected to the positive and negative connections of the battery.
• The first power module includes upper and lower phase switches to control current flow between the battery and the motor.

Potential Applications

This technology can be applied in electric vehicles, renewable energy systems, and industrial machinery where efficient power conversion is required.

Problems Solved

This technology solves the problem of efficiently converting DC power from a battery to AC power for driving motors, improving overall system performance and energy efficiency.

Benefits

The benefits of this technology include improved energy efficiency, reduced power losses, and increased reliability in power conversion systems.

Potential Commercial Applications

The potential commercial applications of this technology include electric vehicles, solar power systems, wind turbines, and industrial automation equipment.

Possible Prior Art

Prior art in power inverter technology includes various designs and configurations for converting DC power to AC power for motor drive applications. Some examples include pulse-width modulation (PWM) inverters and multi-level inverters.

Unanswered Questions

How does this technology compare to existing power inverter designs in terms of efficiency and performance?

This article does not provide a direct comparison with existing power inverter designs, leaving the reader to wonder about the specific advantages and disadvantages of this technology.

What are the potential challenges or limitations of implementing this technology in practical applications?

The article does not address any potential challenges or limitations that may arise when implementing this technology in real-world applications, leaving room for further exploration and discussion on this topic.

Original Abstract Submitted

a system includes: an inverter configured to convert dc power from a battery to ac power to drive a motor, wherein the inverter includes: a first decoupling capacitor configured to be connected to a positive connection of the battery and a negative connection of the battery; and a first power module including: a first upper phase switch configured to control a first upper phase flow of current between the positive connection of the battery and a first phase connection of the motor, and a first lower phase switch configured to control a first lower phase flow of current between a negative connection of the battery and the first phase connection of the motor.