The SLF10145T-150M2R2-2 is a shielded power inductor manufactured by TDK Corporation, part of the SLF10145T series. These inductors are known for their compact design, high inductance values, and robust current handling capabilities. This specific inductor is well-suited for various power management applications where space is a constraint and efficient energy storage is essential.

Applications

• DC-DC Converters
• Power Supplies for Portable Electronics
• LED Lighting Applications
• Buck and Boost Converters
• Voltage Regulators

Features

• Shielded Construction: Effectively minimizes electromagnetic interference (EMI).
• High Inductance Value: 15µH, suitable for various power conversion stages.
• Compact Size: 10.0 x 10.0 x 4.5 mm, facilitating integration in small devices.
• High Current Handling: Supports a rated current of 2.2A.
• Low DC Resistance: Minimizes power loss and maximizes efficiency.
• Operating Temperature Range: -40°C to +125°C (including self-temperature rise).

Benefits

• Reduced EMI: The shielded construction reduces electromagnetic emissions, preventing interference with other nearby components and improving overall system stability.
• Increased Efficiency: Low DC resistance minimizes power dissipation, leading to improved energy efficiency.
• Space Saving: The compact size allows for integration into densely packed circuit boards.
• Reliable Performance: Designed for robust and reliable performance even in demanding environments.
• Stable Inductance: Offers stable inductance characteristics over a wide range of temperatures and frequencies.

Additional Details

The SLF10145T-150M2R2-2 employs a ferrite core material optimized for low core losses and high saturation current. Its terminals are lead-free and RoHS compliant, adhering to environmental regulations. The inductor is designed to operate at high switching frequencies, making it suitable for modern power supply designs. It is crucial to consult the product datasheet for detailed information on saturation current, self-resonant frequency, and temperature derating curves for optimal application.