Abstract
This paper proposes a triple phase shift modulation (TPS) with an optimization technique that aims at maximizing the efficiency of the dual active bridge converter. Such a converter is often used to interface renewable or energy storage systems in smart dc power systems, where loss minimization via TPS is crucial, especially at light-load conditions. In this paper, favorable modulation parameters are found first, aiming at minimum rms currents and zero voltage switching, by considering only some fundamental converter parameters, namely, the input and output voltages, the transformer ratio, and the leakage inductance. Then, on the basis of the closed-form analytical description of the converter behavior over the determined modulation patterns, trajectories in the modulation planes that are capable of improving the total efficiency are identified. It is shown that such trajectories lead to close-to-optimal efficiency operation, which can be exploited to implement fast perturb-and-observe methods requiring just minimal converter parameters knowledge. The results are verified experimentally on a 1.5-kW prototype. It is shown that the proposed approach achieves close-to-optimal efficiency operation under different input voltages, being the error with respect to the measured optimal points obtained by a brute-force approach lower than about 0.2%.
Highlights
DC-DC electronic power converter (EPC) are widely used in modern energy processing applications
The mentioned efficiency improvements are obtained by a triple phase shift modulation (TPS) approach and an efficiency maximization procedure, called maximum efficiency point identification (MEPI) algorithm, that aim at optimal operating conditions especially at light-load
For the implementation of the TPS and the efficiency maximization approach, each pattern shown in Fig. 3 can be analyzed separately
Summary
DC-DC electronic power converter (EPC) are widely used in modern energy processing applications. TPS strategies for conduction loss and efficiency optimization have been proposed, for example, in [4], [5], [23], [24] These modulations make use of accurate models of the converter operation and loss contributions [25], which may be not always retrievable and deployable. The mentioned efficiency improvements are obtained by a TPS approach and an efficiency maximization procedure, called maximum efficiency point identification (MEPI) algorithm, that aim at optimal operating conditions especially at light-load This is achieved by topology analysis and by using simple models and basic information on the converter parameters. This can be verified considering a specific design by means of the modified Steinmetz equation [37]
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