The 16SVPG47M is a high-performance aluminum electrolytic capacitor from Rubycon, designed for applications requiring stable energy storage and filtering in power electronics. Housed in a radial-leaded cylindrical package, this capacitor features a capacitance of 470 µF with a rated voltage of 63V. It is optimized for high ripple current handling and long-term reliability in harsh electrical environments, making it suitable for industrial, automotive, and power supply systems.

Key Features

This capacitor combines a low equivalent series resistance (ESR) of 11 mΩ (typical at 100 kHz) with a maximum ripple current rating of 2.5 A (at 100 kHz, 85°C), enabling efficient energy dissipation in high-frequency applications. It operates over a wide temperature range of -40°C to +105°C, ensuring stability in extreme conditions. The 16SVPG47M employs a self-healing aluminum electrolytic construction, minimizing failure risks from internal shorts. Its compact size (16 mm diameter × 35 mm height) and robust design provide space-saving integration while maintaining high capacitance density.

Applications

Primarily used in power factor correction (PFC) circuits, SMPS (switch-mode power supplies), and motor drives, the 16SVPG47M excels in applications demanding high ripple current handling, such as renewable energy inverters, UPS systems, and industrial automation equipment. It is also employed in automotive electronics for battery energy storage and DC-DC converter filtering. Its reliability and thermal tolerance make it suitable for LED lighting drivers and telecom power systems.

Summary

The 16SVPG47M combines high capacitance, low ESR, and rugged durability, making it a critical component for power management systems requiring reliable energy storage and filtering. Its compact form factor, wide operating temperature range, and self-healing capability ensure robust performance in demanding applications across industrial, automotive, and energy sectors. This capacitor is essential for engineers designing circuits that demand efficient power handling and longevity under harsh conditions.