Honeywell international inc. (20240348169). DC-DC CONVERTER CIRCUIT simplified abstract
Contents
DC-DC CONVERTER CIRCUIT
Organization Name
Inventor(s)
DC-DC CONVERTER CIRCUIT - A simplified explanation of the abstract
This abstract first appeared for US patent application 20240348169 titled 'DC-DC CONVERTER CIRCUIT
The abstract of the patent application describes a DC-DC converter circuit that includes various components such as high-side and low-side transistors, a gate driver power supply, a converter control, and a capacitance divider network. The high-side transistor is connected to a positive DC supply terminal and is controlled by the converter control. The gate driver power supply is isolated from the transistors, and the capacitance divider network includes two capacitors connected in series.
- High-side and low-side transistors
- Gate driver power supply
- Converter control
- Capacitance divider network
- Isolation of gate driver power supply
- Series connection of capacitors in the capacitance divider network
Potential Applications: - Power electronics - Renewable energy systems - Electric vehicles
Problems Solved: - Efficient power conversion - Control of high-side and low-side transistors
Benefits: - Improved energy efficiency - Enhanced control of power electronics systems
Commercial Applications: Title: "Advanced DC-DC Converter Circuit for Power Electronics Applications" This technology can be used in various industries such as renewable energy, electric vehicles, and industrial automation for efficient power conversion and control.
Prior Art: Research existing patents related to DC-DC converter circuits and power electronics control systems to understand the current state of the art in this field.
Frequently Updated Research: Stay updated on advancements in power electronics, semiconductor technology, and control systems to enhance the performance of DC-DC converter circuits.
Questions about DC-DC Converter Circuits: 1. How does the isolation of the gate driver power supply benefit the overall performance of the circuit?
The isolation of the gate driver power supply helps prevent interference and ensures stable operation of the transistors.
2. What are the key factors to consider when designing a capacitance divider network for a DC-DC converter circuit?
The capacitance values, voltage ratings, and placement of the capacitors are crucial in designing an effective capacitance divider network.
Original Abstract Submitted
a dc-dc converter circuit includes a high-side transistor, a low side transistor, a gate driver power supply, a converter control, and a capacitance divider network. the high-side transistor includes a high-side drain terminal, a high-side source terminal, and a high-side gate terminal. the high-side drain terminal is coupled to a positive dc supply terminal. the gate driver power supply is electrically isolated from the high-side transistor and the low-side transistor. the converter control is configured to supply high-side control commands and low-side control commands to the high-side transistor and the low-side transistor, respectively. the capacitance divider network includes a first capacitor and a second capacitor. the first capacitor is electrically connected in series, at a dc-link midpoint node, to the second capacitor. the dc-link midpoint node, the gate driver power supply, and the converter control are all electrically connected to, and share, a local electrical ground.
