The MBRD1060CT-G is a robust Schottky rectifier designed by Diodes Incorporated, renowned for its high efficiency and low power loss characteristics. This component is particularly well-suited for applications requiring fast switching and low voltage drop, making it an ideal choice for high-frequency operations and energy-sensitive circuits.
Key Features
- High Current Capability: The device can handle a continuous forward current of up to 10A, providing ample headroom for high-current applications.
- Low Forward Voltage Drop: With a forward voltage drop typically under 0.83V, this Schottky rectifier ensures minimal power loss, enhancing overall system efficiency.
- Dual Rectifier Configuration: The MBRD1060CT-G features a common cathode dual rectifier configuration, allowing for use in a variety of circuit topologies.
- High Surge Capability: It is designed to withstand surge currents, ensuring reliability and robust performance under stress conditions.
- Wide Operating Temperature Range: This device operates effectively across a broad temperature range from -55°C to +150°C, suitable for challenging environments.
Applications
The MBRD1060CT-G is versatile and can be used in a multitude of applications including:
- Power supply units
- DC-DC converters
- Free-wheeling diodes in converters and motor control circuits
- Automotive applications
- Reverse battery protection
Quality and Reliability
Diodes Incorporated ensures that the MBRD1060CT-G meets stringent quality standards. The device is packaged in a TO-252 (DPAK) package, which provides a compact footprint while allowing for adequate heat dissipation. It is also RoHS compliant, adhering to current environmental standards, and is characterized for moisture sensitivity in accordance with the Pb-free reflow requirements of the joint IPC/JEDEC standard J-STD-020.
With its combination of efficiency, durability, and versatility, the MBRD1060CT-G Schottky rectifier from Diodes Incorporated is an excellent choice for designers looking to improve the performance and reliability of their power management systems.