2020 journal article

Capacitor Voltage Balancing for Neutral Point Clamped Dual Active Bridge Converters

IEEE TRANSACTIONS ON POWER ELECTRONICS, 35(10), 11267–11276.

author keywords: Capacitors; Switches; Bridge circuits; Voltage control; Topology; Voltage measurement; Legged locomotion; Capacitor voltage balancing; dual active bridge (DAB); neutral point diode clamped (NPC); neutral point balancing
TL;DR: A voltage balancing controller, which is independent of power flow direction and does not require adjustments of active voltage vectors through the modulator, is proposed and demonstrated through analysis, simulation, and hardware experiments using a laboratory prototype. (via Semantic Scholar)
UN Sustainable Development Goal Categories
7. Affordable and Clean Energy (Web of Science; OpenAlex)
Source: Web Of Science
Added: July 20, 2020

A capacitor voltage balancing method is proposed for a full-bridge neutral point diode clamped (NPC) dual-active bridge (DAB) converter. In existing literature, capacitor voltage balancing is achieved by actively selecting between the small voltage vectors, i.e., connecting either the upper or the lower capacitor on the dc bus to the transformer winding, on the basis of measured voltage mismatch. These balancing methods are dependent on the direction of power flow through the DAB converter. In this work, we propose a voltage balancing controller, which is independent of power flow direction and does not require adjustments of active voltage vectors through the modulator. Irrespective of the direction of transformer current, by dynamically shifting the switching instants of the inner switch pairs in the two NPC legs during the free-wheeling/zero voltage vector time, either of the two capacitors can be selectively charged without introducing any offsets in the voltage-second seen by the transformer. A simple bidirectional phase-shift modulator is designed to facilitate voltage balancing irrespective of power flow direction or mode of operation. The proposed method is highly and universally effective under any converter operating condition and was verified and demonstrated through analysis, simulation, and hardware experiments using a laboratory prototype.