The ASWPA4035S470MT is a wire-wound power inductor manufactured by Sunlord. It is designed for a wide range of power applications, offering excellent performance in a compact size.

Applications:

• DC-DC converters
• Power supplies
• Laptop computers
• Portable communication equipment
• LED lighting

Features:

• Wire-Wound Construction: Provides high current capability and excellent energy storage.
• Shielded Construction: Minimizes electromagnetic interference (EMI).
• Compact Size: Dimensions of 4.0mm x 4.0mm x 3.5mm, suitable for space-constrained applications.
• High Current Rating: Capable of handling significant current levels without saturation.
• Low DC Resistance (DCR): Minimizes power losses and improves efficiency.
• Operating Temperature Range: Designed to operate reliably over a wide temperature range.

Benefits:

• High Efficiency: Low DCR reduces power losses, leading to improved energy efficiency in power circuits.
• Reduced EMI: Shielded construction minimizes electromagnetic interference, ensuring stable operation of nearby components.
• Space Saving: Compact size allows for higher component density on the PCB.
• Reliable Performance: Robust construction and high current capability ensure reliable operation in demanding applications.
• Versatile Application: Suitable for a wide range of power applications, offering flexibility in design.

Additional Details:

Specifications:

• Inductance: 47µH
• Tolerance: 20%
• Saturation Current: Available in manufacturer datasheets
• DC Resistance (DCR): Available in manufacturer datasheets
• Shielded: Yes
• Operating Temperature: -40°C to +125°C (including self-heating)
• Dimensions: 4.0mm x 4.0mm x 3.5mm

Materials:

• Core Material: Ferrite
• Wire Material: Copper
• Shield Material: Ferrite

The ASWPA4035S470MT from Sunlord is a high-performance, shielded wire-wound inductor designed for efficient power conversion in various electronic devices. Its compact size, high current capability, and low DCR make it an excellent choice for demanding applications where space and efficiency are critical.