The B260-13-F is a high-quality Schottky barrier rectifier designed and manufactured by Diodes Incorporated, a leading company in the semiconductor market. This rectifier is specifically engineered to offer efficient and reliable performance for a wide range of applications, including power supply, converter, and high-frequency circuits.

Key Features

• Low Forward Voltage Drop: The device features a low forward voltage drop, which enhances power efficiency by minimizing power loss during operation.
• High Surge Capability: With its robust surge capability, the B260-13-F can withstand transient over-voltage conditions, ensuring reliable performance and longevity of the device.
• Guard Ring Die Construction: The guard ring design provides enhanced reliability through transient protection, safeguarding the device from excessive voltage spikes.
• High Current Capability: This rectifier can handle high current loads, making it suitable for applications requiring a high current throughput.

Electrical Characteristics

The B260-13-F boasts a maximum repetitive reverse voltage of 60V and a forward continuous current of 2A. Its power and thermal characteristics are designed to maintain stability and functionality even under high-load conditions.

Applications

Due to its robust design and electrical properties, the B260-13-F is ideal for a variety of applications, including:

• Switching power supplies
• Converters
• Free-wheeling diodes
• Reverse battery protection
• DC-DC converters
• Automotive applications

Package and Quality Assurance

The B260-13-F is available in an SMB package, which is known for its compact size and suitability for automated assembly processes. Diodes Incorporated ensures that each unit meets rigorous quality standards, providing customers with a reliable and consistent product.

Whether you're designing a sophisticated power management system or looking for a dependable component for your electronic designs, the B260-13-F Schottky barrier rectifier from Diodes Incorporated is a choice that promises performance, efficiency, and quality.