A DC Voltage Swell Compensator Based on SMES Emulator and Lead-Acid Battery

The fast-response feature from a superconducting magnetic energy storage (SMES) device is favored for suppressing instantaneous voltage and power fluctuations, while the low-cost feature from a conventional battery energy storage (BES) device suits to achieve long-time voltage and power compensations in the power distribution and utilization systems. This paper investigates a new dc voltage swell compensating scheme by using an SMES-BES-based hybrid energy storage technology. In the preliminary tests, an iron-core copper coil is used to imitate high-temperature superconducting inductor, and this SMES emulator is, then, combined with a lead-acid battery to form a dc voltage swell compensator device. The experimental results demonstrate the feasibility of this SMES-BES-based dc voltage swell compensator to avoid the initial impulse charging current for the lead-acid battery and to extend the steady compensating time duration for the SMES simultaneously.

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